SUMMARY
To reveal the role of the essential protein Era in the assembly of the 30S ribosomal subunit, we analyzed assembly intermediates that accumulated in Era-depleted Escherichia coli cells using quantitative mass spectrometry, cryo-electron microscopy and in-cell footprinting. Our combined approach allowed for visualization of the small subunit as it assembled and revealed that with the exception of key helices in the platform domain, all other 16S rRNA domains were able to fold even in the absence of Era. Notably, the maturing particles did not stall while waiting for the platform domain to mature and instead re-routed their folding pathway to enable concerted maturation of other structural motifs spanning multiple rRNA domains. We also found that binding of Era to the mature 30S subunit destabilized helix 44 and the decoding center preventing binding of YjeQ, another assembly factor. This work establishes Era’s role in ribosome assembly and suggests new roles in maintaining ribosome homeostasis.
INTRODUCTION
The bacterial 70S ribosome is made of the small (30S) and large (50S) subunits and consists of over fifty different ribosomal proteins (r-proteins) and ribosomal RNA (rRNA) that must fold and associate. During this assembly, the 16S rRNA in the 30S subunit and the 23S and 5S rRNA molecules in the 50S subunit fold according to energy landscapes comprised of multiple parallel assembly pathways (Adilakshmi et al., 2005; Talkington et al., 2005). In vivo, ribosome biogenesis is aided by subunit-specific protein assembly factors that enable rapid (~two minutes) and efficient ribosome biogenesis (Shajani et al., 2011). Although the specific function of most of these assembly factors is still unclear, they are generally thought to act by binding to the maturing particles and modifying their energy landscapes to favor folding pathways and to prevent the rRNA from falling into local energy minima (Talkington et al., 2005).
The ribosome assembly factor Era (Escherichia coli Ras-like) is known to participate in 30S subunit maturation, however its precise role is still largely unknown. This protein is universally conserved in both eukaryotes and prokaryotes (Leipe et al., 2002) and it is essential for both Gram-negative (Anderson et al., 1996; March et al., 1988; Takiff et al., 1989) and Gram-positive bacteria (Minkovsky et al., 2002; Sato et al., 1998). Era is comprised of a N-terminal GTPase domain and a C-terminal KH (K-homologue) domain connected by a 17 amino acid long flexible linker whose length is important for its function (Inoue et al., 2003). The GTPase domain consists of a central β-sheet flanked by five helices. The KH domain has a high structural similarity to the RbfA assembly factor and folds following a type 2 (αββααβ) KH folding pattern. This KH domain is necessary for Era to bind the 16S rRNA and the 30S subunit (Hang and Zhao, 2003; Johnstone et al., 1999).
Crystallography studies with purified Era and RNA fragments derived from the 3’ end of the 16S rRNA (Tu et al., 2009) revealed that the two domains of Era can adopt a ‘closed’ and an ‘open’ conformation. In the apo or GDP-bound states, Era adopts the open conformation in which the nucleotide binding site is accessible but the RNA binding site in the KH domain is occluded. Binding of GTP is thought to drive Era to the closed state, thus allowing for rRNA binding (Chen et al., 1999; Ji, 2016; Tu et al., 2009). According to this model, subsequent rRNA binding, which is known to stimulate GTP hydrolysis (Tu et al., 2009), would then revert Era to the open state and trigger release of Era from the rRNA. These findings are consistent with equilibrium binding assays in which Era exhibited increased affinity for rRNA in the presence of GDPNP, a non-hydrolyzable GTP mimic, relative to that in the presence of GDP (Sayed et al., 1999; Thurlow et al., 2016).
Although binding to the isolated rRNA fragment can be modeled by this two-state conformational switch model, Era may adopt additional conformations when bound to entire 30S subunit. Indeed, a low resolution cryo-electron microscopy (cryo-EM) structure of Era in complex with the 30S subunit found that neither of the aforementioned conformations were compatible with the orientation of the two domains of Era when the factor was bound to the cleft region between the head and platform on the 30S subunit (Sharma et al., 2005).
To determine the role of Era in the 30S subunit assembly, we employed quantitative mass spectrometry (qMS), high-resolution cryo-electron microscopy (cryo-EM) and in-cell footprinting to analyze 30S subunit assembly intermediates (30SEra-depleted particles) that accumulated in Escherichia coli under Era depletion conditions. In addition, we investigated a potential role of Era in ribosomal quality control and we further explored the functional interplay between Era and another assembly factor, YjeQ (Campbell and Brown, 2008).
Here, we found that in the absence of Era, all of the major 16S rRNA domains fold correctly with the exception of helices 23 and 24 in the platform region, suggesting that maturation of these helices directly or indirectly relies on Era. Notably, our structures indicate that the assembling particles did not stall at the maturation step folding helices 23 and 24. Instead, particles skipped the folding of these two helices and were re-routed in their folding pathway to continue the maturation of other structural motifs. This analysis suggests that assembly of the 30S subunit is not necessarily sequential (from 5’ to 3’) and that at least in the absence of Era, all three major domains of the 16S rRNA can co-mature. Further, we found that treatment of mature 30S subunits with Era destabilizes functionally essential regions of the particle and inhibits binding of YjeQ. Overall, these results suggest that Era binds to the immature 30S subunit independently from YjeQ. The observed ability of Era to induce significant conformational changes in the mature 30S subunit also suggests new roles of this protein in ribosome homeostasis.
RESULTS
Era depletion causes accumulation of 30S subunit assembly intermediates
We created a strain that allowed for the controlled expression of Era under an arabinose inducible promoter and we used it to determine how Era depletion impacts the distribution of ribosomal particles and their protein composition in E. coli cells. This strain exhibited a growth phenotype consistent with previously characterized Era-depleted strains (Supplemental results and Figure S1). Crude ribosomes were extracted from cells grown under permissive (+arabinose) and restrictive (-arabinose) conditions, layered onto a 10%–30% (w/v) sucrose gradient and subjected to ultracentrifugation. In wild type E. coli cells, between 2-5% of the 30S subunits remain typically dissociated instead of forming 70S ribosomes (Leong et al., 2013; Thurlow et al., 2016). Consistent with that data, 3% of the 30S subunits were found dissociated from 50S subunits when the strain was grown under permissive conditions. However, growth in restrictive conditions increased the percentage of free 30S subunits to 72%, significantly decreasing the proportion of 70S ribosomes (Figure 1A; top panel). This percentage was significantly higher than what has been reported in the past for other non-essential assembly factor knock-out strains (ΔrimM, ΔyjeQ, ΔrbfA) (Guo et al., 2013; Himeno et al., 2004; Leong et al., 2013; Thurlow et al., 2016) consistent with a more substantial defect in the 30S subunit assembly process.
Next, we used quantitative mass spectrometry (qMS) to determine the r-protein composition of the 30S particles purified from either parental or Era-depleted strains. Based on their occupancy levels in the 30SEra-depleted particles, r-proteins were divided into 3 groups (Figure 1B and Figure S2). Group 1 included most r-proteins, which were present stoichiometrically in all 30S particles, suggesting that their binding was independent of Era. Conversely, group 3 proteins bS1 and bS21 were completely missing from 30SEra-depleted particles revealing that their binding was severely affected by Era depletion. Finally, group 2 proteins uS2, uS3 and uS5 showed intermediate occupancy levels in 30SEra-depleted particles, suggesting a partial Era-dependence for their binding. We noted that occupancy of bS20 was sub-stoichiometric in small subunit particles derived from either Era-depleted cells or parental cells, consistent with protein dissociation during purification of the subunits.
Painting the Nomura map (Traub and Nomura, 1968, 1969a, b) according to these r-protein groups (Figure 1C) revealed that the protein complement of the 30SEra-depleted particles is consistent with the binding hierarchy defined by the assembly map. Inspection of mature 30S subunit crystal structure (Schuwirth et al., 2005) and cross-linking mass spectrometry data localizing bS1 binding site (Lauber et al., 2012) showed that sub-stoichiometrically bound proteins (group 2 and 3) associate near the Era binding site on the platform region of the particle (Sharma et al., 2005) (Figure 1D). The conspicuous co-localization of these r-proteins suggested that Era may be assisting entry of these proteins.
Taken together this analysis showed that a large proportion of the particles isolated form Era-depleted cells were immature and in the late stages of the assembly process.
The immature 30S particles accumulating in the Era-depleted strain range from early to late assembly intermediates
To further understand the role of Era in the assembly of the 30S subunit, we determined an ensemble of structures present in the 30SEra-depleted particles using high-throughput, single particle cryo-EM. Our dataset included over 800,000 particle images of purified 30SEra-depleted particles and, after subjecting this dataset to multiple rounds of 3D image classification and initial map determination, we obtained a collection of sixteen cryo-EM maps (Figure 2).
These sixteen cryo-EM maps provide a direct visualization of the 30S subunit as it assembled (Movie 1). Classes A, B, and C represented particles at very early stages of assembly. These particles exhibited density corresponding to the body of the 30S subunit and lacked platform or head domains. Notably, in these maps the body had not fully matured as rRNA helices could not be readily assigned. Class D contained particles appearing to undergo maturation of the body and platform, but without starting to significantly fold the head. Classes E to H appeared to be folding the three domains simultaneously. The remaining classes (I-P) resembled successively more mature assembly intermediates with body, platform and head domains progressively closer in structure to the mature subunit. No class corresponding to fully mature 30S subunit was observed.
Our structures of isolated body domains (classes A-C), which are composed of the 5’ and central domains are largely in agreement with previous work establishing that rRNA folding occurs 5’ to 3’ (Powers and Noller, 1990; Talkington et al., 2005). Notably however, the observed co-maturation of the body, platform, and head domains in classes E-P indicates that, at least in the absence of Era, rRNA folding is not necessarily sequential and that maturation of all three major domains of the 16S rRNA can occur in concert.
Particles assigned to classes D and P represented the 22% and 50% of the population, respectively and it was possible to obtain high-resolution structures for these assembly intermediates (see section below). All the other remaining classes accumulated only 28% of the particle population and consequently only rendered maps at modest resolution (10-15 Å). However, they still provided sufficient detail to visualize the overall folding of the 16S rRNA domains (Figure 2 and Movie 1).
Folding of the platform domain of the 30S subunit requires Era
The map for class D refined to 4.8 Å resolution (Figure 3A and Figure S3A). Local resolution analysis showed that the body of the particle is the most defined region, whereas the platform is less well resolved, likely due to intrinsic flexibility caused by the maturation events still ongoing in this domain (Figure S3B). As we were unable to build an atomic model at this resolution, we docked the X-ray structure of a complete 30S subunit (Schuwirth et al., 2005) into this map to visualize how structural elements in class D deviated from the mature structure. This analysis revealed that the density corresponding to the head domain was completely missing in the cryo-EM map of the assembly intermediate whereas density for the rRNA in the body and platform was present. Notably, the body and platform density observed deviated substantially from the tracing of the atomic model of the mature 30S subunit indicating that these regions are still in an immature conformation. The cryo-EM map was also missing density for all the r-proteins in the head, as well as uS2 and uS5 in the body and bS21 in the platform.
The cryo-EM map for class P, the most mature of the assembly intermediates, refined to 3.8 Å resolution (Figure 3B and Figure S3A) with the highest local resolution in the body region of the map. Peripheral domains including the front of the head and platform regions exhibited lower local resolution, again consistent with an intermediate still undergoing maturation. The resolution of this cryo-EM map was sufficient to produce an atomic model from the cryo-EM map (Figure S4), which we used to compare this assembly intermediate to the mature 30S subunit (Figure 3C and Movie 2). The platform and 3’ minor domain exhibited the most striking structural differences. Indeed, in the platform, density for helices 23 and 24 was absent or highly fragmented, and helices 44 and 45 (nucleotides 1397-1534) of the 3’ minor domain were completely invisible (Movie 2). We interpret these fragmented regions of the map as indications that these elements have not fully matured. Finally, all structural elements were present in the head domain, but this entire rigid body was tilted away from the platform (Figure 3D). The remainder of the structure was largely indistinguishable from the mature subunit and exhibited complete density for r-proteins in all four domains except for uS7, uS9, uS13 and uS19 in the head, and uS11 and bS21 in the platform, which each showed a highly fragmented density or lacked density completely (Figure 3B and Movie 2). Combining this structure with our qMS data (Figure 1A), we concluded that proteins bS21 and bS1 are completely absent whereas proteins uS7, uS9, uS11, uS13, and uS19 are likely bound in a flexible manner not easily resolved by cryo-EM. The structural differences of class P with the mature subunit suggests that during the folding of the platform domain, helices 23 and 24 failed to adopt the mature conformation in the absence of Era. However, the assembling particles were able to skip the folding of this motif and re-route their assembly pathway to continue with the maturation of the head domain, which is downstream of helices 23 and 24 (Besancon and Wagner, 1999; Mulder et al., 2010; Sashital et al., 2014; Sykes and Williamson, 2009). Therefore, we concluded that the folding of helices 23 and 24 represents a critical folding barrier during 30S subunit maturation and Era mediates efficient folding of these helices.
Era expression promotes maturation of helix 23 and 24 in the 30S subunit platform domain
We next used dimethyl sulfate (DMS) footprinting to inspect the structure of the 16S rRNA platform domain with single nucleotide resolution in various Era-limited cells. Specifically, cells were collected before Era depletion (Era pre), after Era depletion (Era depleted) and at various times after Era re-expression (Era+) and were treated with DMS for 0.5 min, 1 min or 2 min (Figure 4A), and the methylation pattern in the 16S central domain was detected by primer extension (Figure 4B and Figure S5). We mapped the 5’ end of the rRNA by primer extension to confirm that the ratio of immature 17S to mature 16S RNA increased upon Era depletion and decreased when Era expression was restored (Figure S6).
We found that helices 23 and 24 in the central domain were highly modified by DMS in Era depleted samples, compared to cells probed before Era depletion (Era pre) or after Era was re-induced (Era+) (red and orange in Figure 4B and 4C). This result is consistent with the cryo-EM maps obtained for the 30SEra-depleted particles purified from cells grown under Era depletion conditions. All of these structures exhibited non-mature conformations of the platform domain and had missing or broken densities for helices 23 and h24. In sum, these results confirm that these two helices were not natively folded in the absence of Era. Likewise, nucleotides in helix 22 also showed increased DMS modification upon Era depletion and enhanced protection when Era was restored, suggesting that Era directly or indirectly stabilizes the structure of helix 22 (orange in Figure 4B and 4C). As density for helix 22 is observed in the class P cryo-EM maps, this chemical probing result implies that helix 22 is likely immature in most of the other classes (classes A to O), which constitute ~50% of all Era-depleted particles (Figure 2). We also observed delayed changes to the DMS modification pattern of helix 21, in which an internal bulge in helix 21 folds only 1 hour after Era re-expression (blue in Figure 4C and Figure S5C). The base of helix 21 is recognized by ribosomal protein uS8, but its tip extends away from the central domain to contact the solvent side of the 30S subunit 5’ domain. This timing suggests that Era enables structural changes at the interface of the 5’ and 3’ domains during 30S assembly, in agreement with previous in vitro footprinting results that revealed conformational changes in the region around r-protein uS8 and slow folding of h21 during 30S assembly (Adilakshmi et al., 2008; Calidas and Culver, 2011). Taken together, our in-cell DMS probing results are consistent with the observed cryo-EM structures and highlight Era’s role in assembly of the 30S subunit platform.
Era binding to the mature 30S subunit destabilizes helix 44 and decoding center
Cells often employ quality control mechanisms to survey nascent ribosomes and ensure their functionality (Karbstein, 2013; Strunk et al., 2011; Strunk et al., 2012). Recently, it was suggested that in addition to its function as an assembly factor, YjeQ may also test the proofreading ability of the 30S subunit (Razi et al., 2017). Thus, to investigate a potential role for Era in ribosome quality control, we assayed Era’s ability to interact with mature ribosomes, and determined the effect of this interaction in the 30S subunit using cryo-EM. We first tested the ability of Era to interact with the mature 30S subunit using a dissociation experiment (Lopez-Alonso et al., 2017). This assay exploits the ability of Era to split 70S ribosomes into 50S and 30S subunits (Sharma et al., 2005). Era was mixed and incubated with purified 70S ribosomes in buffer containing either GDP, GTP, GDPPNP or no nucleotide. Subsequently, ribosomal particles were separated by sucrose density ultracentrifugation (Figure 5A). We found that most of the ribosomes remained as 70S particles after mixing a 5-fold excess of Era in the absence of nucleotide. However, we observed significant 70S dissociation when Era was added in the presence of buffer containing one of the nucleotides. Effective splitting was both nucleotide-and Era-dependent as incubation of 70S particles with GDPPNP alone had no effect.
Taking these results into consideration, we mixed mature 30S subunits with Era in a buffer containing GDPPNP and collected images using cryo-EM. Single particle analysis of these images produced a cryo-EM map that refined to 3.9 Å resolution (Figure S7A). Local resolution analysis showed that the highest resolution values were observed in the body domain of the subunit. Peripheral domains including the front of the head and platform regions exhibited lower resolution suggesting higher flexibility in these domains (Figure S7B).
A previous cryo-EM structure showed that in Thermus thermophilus, Era bound the mature 30S subunit at the cleft region between platform and head (Sharma et al., 2005). However, the moderate resolution (~13Å) of this structure precluded detailed analysis of any Era-induced structural changes in the 30S subunit. The structure obtained herein (Figure 5B and 5C and Movie 3) revealed significant Era-induced conformational changes in the 3’ minor domain of the mature 30S (Schuwirth et al., 2005). For example, density for helix 44 was completely invisible, and density at the tips of helices 23 and 24 was mildly fragmented (Figure 5B). Density was also lacking for bS1, uS7, bS21, and the N-terminal region of uS13 (Figure 5B and 5C). All other regions of the structure resembled the mature 30S subunit. Surprisingly, we could only observe a small and fragmented density near uS2 in the cleft region between platform and head that could be assigned to Era, suggesting that that unlike T. thermophilus Era, E. coli Era binds to this region either transiently or in a flexible manner (Figure 5C). In conclusion, this structure suggests that Era has the ability to destabilize functionally essential regions of the mature 30S subunit, including the key elements of the decoding center such as helices 44, 22, and 23.
Era destabilization of helix 44 blocks binding of YjeQ to the 30S subunit
Previously, Cambell and Brown showed that overexpression of Era suppresses the slow growth phenotype of ΔyjeQ cells suggesting a functional interplay between the factors (Campbell and Brown, 2008). Thus, we investigated whether these factors could simultaneously bind the mature 30S, and whether the presence of YjeQ could stabilize Era binding. First, we used microscale thermophoresis (MST) to measure whether pre-binding of Era to the 30S subunit affected the binding of YjeQ to the 30S. Consistent with previous studies (Thurlow et al., 2016), YjeQ exhibited high binding affinity to the 30S subunit with a Kd value of 58.5 ± 47 nM. However, mixing a 10-fold or a 20-fold molar excess of Era with the 30S subunits prior to addition of YjeQ, increased the Kd of the interaction between YjeQ and mature 30S subunits to 1.1 ± 0.6 μM and 2.3 ± 1.2 μM, respectively. These results indicated that binding of Era to the 30S subunit dramatically decreased the affinity of YjeQ for the 30S subunit.
Next, we set up an assembly reaction containing mature 30S subunits plus a molar excess of YjeQ and Era. Single particle analysis produced a cryo-EM map at 3.5 Å resolution (Figure S8A). The highest resolution values were observed in the body domain, whereas the front of the head and platform regions exhibited higher flexibility and produced a map with lower resolution values (Figure S8B).
Previously published structures showed that YjeQ binds to the decoding center and stabilizes helix 44 (Guo et al., 2011; Jomaa et al., 2011b; Lopez-Alonso et al., 2017; Razi et al., 2017). However, we found no additional density in this area of the map that could be assigned to YjeQ and helix 44 was also completely unfolded (Figure 6B). Like the reaction containing mature 30S subunits and Era protein, the cyo-EM map obtained from the reaction containing small subunits and both Era and YjeQ (Movie 4) lacked density for uS7 and the N-terminal region of uS13 (Figure 6B) but showed a defined density for bS21 (Figure 6C). In this case, the map presented a highly fragmented density in the cleft region between the head and platform, which is thought to be the Era binding site to the mature 30S subunit (Sharma et al., 2005). Masked classification on the Era binding region with subtraction of the signal from the rest of the complex did not define this density with sufficient details to unambiguously assign it to Era (Figure 6C). This cryo-EM map allowed us to conclude that the mechanism by which Era decreases the affinity of YjeQ for the mature 30S subunit is by inducing the undocking of helix 44.
DISCUSSION
Role of Era in 30S subunit assembly
Prior structural and biochemical analysis of the immature 30S particles that accumulate in ΔyjeQ (Jomaa et al., 2011a), ΔrimM (Guo et al., 2013; Leong et al., 2013), ΔrimP (Sashital et al., 2014) and ΔyjeQΔrbfA (Yang et al., 2014) strains have proven powerful in identifying the role of these nonessential assembly factors. Similar approaches have been applied to study the assembly process of the 50S subunit either by genetically removing assembly factors (Ni et al., 2016) or essential r-proteins (Davis et al., 2016). Here, we have extended this methodology to the essential 30S subunit assembly factor Era and employed high-throughput cryo-EM data collection to achieve higher resolution than was possible in prior studies of the 30S.
Previous negative staining EM visualization of 30S particles isolated from wild type E. coli and a ΔrimP strains (Sashital et al., 2014) and from in vitro reconstitution reactions (Mulder et al., 2010) revealed that assembly of the 30S subunit is sequential (from 5’ to 3’) and that folding of the head domain only occurs upon completion of the folding of the 5’ and central domain. In striking difference, our cryo-EM analysis suggests that in the assembly of the 30S subunit, at least in the absence of Era, all three major domains of the 16S rRNA can co-mature. In particular, classes E to H identified within the 30SEra-depleted particle population (Figure 2) appeared to be clearly folding the three domains simultaneously.
Our structures also revealed that most 16S rRNA elements were able to fold even when Era was depleted. Notably, we found that helices 23 and 24 in the platform domain failed to mature upon Era depletion. Given their proximity to the putative Era binding site, we posit that Era is directly involved in the maturation of helices 23 and 24. As described above, helices 23 and 24 are thought to mature early in the assembly process when Era is present (Besancon and Wagner, 1999; Mulder et al., 2010; Sashital et al., 2014; Sykes and Williamson, 2009) and, if ribosome assembly is strictly sequential, one would have expected assembly to stall at this point and the accumulated intermediates to be very immature (Figure 7). Instead, we observe a significant number of late assembly intermediates (classes G to P), implying that particles re-routed their folding pathway to continue the maturation of their other structural motifs (Figure 7) while waiting for maturation of Era-dependent elements.
The large percentage (22%) of particles adopting the conformation described by class D probably represent the assembly intermediates unsuccessfully attempting to properly fold these helices, but before finding an alternative assembly pathway to continue their maturation and producing the subsequent classes (classes F to P). This interpretation aligns well with previous studies establishing that assembly of the 30S subunit occurs through multiple parallel assembly pathways (Adilakshmi et al., 2005; Talkington et al., 2005) and recent work illustrating dynamic re-routing of assembly flux through parallel pathways in the large subunit (Davis et al., 2016).
Interestingly, helices 44 and 45 are also immature in each of our structures suggesting that their maturation either directly depends on Era or, instead, requires proper maturation of helices 23 and 24 in the platform domain. We favor the later model as folding of helix 44 and 45 including the decoding center are thought to be final maturation steps before the 30S subunit becomes functionally active and the factors YjeQ and RbfA have previously been implicated in facilitating this step (Clatterbuck Soper et al., 2013; Jomaa et al., 2011a; Lopez-Alonso et al., 2017; Razi et al., 2017).
Role of Era in ribosome homeostasis
Prior structural work (Sharma et al., 2005; Tu et al., 2009) has also suggested that Era might block premature translation initiation by immature small subunit particles. Suggested models include: i) blocking access to the anti-Shine-Dalgarno (SD) sequence near the 3’ end of the 16S rRNA; and ii) preventing the binding of bS1, a r-protein necessary for the SD / anti-SD interaction to the 30S subunit. The 70S dissociation experiments performed herein indicate that Era may also prevent translation initiation by mature 30S subunits. Our subsequent structural analysis of the mature 30S particles treated with Era revealed a complete unfolding of helix 44 and reversion of the decoding center to an immature state. As helix 44 contains the b2a inter-subunit bridge that is essential for subunit joining, this Era-treated particle would not be competent for translation.
Reversion of ribosomal structural motifs to an immature state is not unprecedented. Indeed, earlier studies have described this phenomenon upon removal of r-proteins (Jomaa et al., 2014) or binding of the assembly factor YjeQ (Lopez-Alonso et al., 2017). Our analysis demonstrates that Era shares this ability and opens the possibility that cells may utilize these assembly factors to revert mature, active ribosomes into inactive, immature particles. The physiological conditions in which this function of Era or other assembly factors sharing this ability becomes relevant for survival or fitness is still unclear. Possibilities include the participation of Era on active dissociation of hibernating RMF (ribosome modulation factor) HFP (hibernation promoting factor)-100S and RaiA (ribosome-associated inhibitor A)-70S ribosomes that E. coli assembles during stationary phase to stop protein synthesis and reduce energy consumption (Prossliner et al., 2018). A recent publication has provided the first insight into GTP-dependent dissociation mechanisms of 100S ribosomes by the widely conserved GTPase HflX (Basu and Yap, 2017). However, deletion of hflX had only a moderate effect on the fraction of dimerized ribosomes, suggesting that HflX is not solely responsible for dissociation and that other protein factors such as Era, could also be involved in the reactivation mechanisms. It is also plausible the cell uses Era and other destabilizing assembly factors to initiate ribosome degradation during starvation. Conditions that increase the formation of ribosomal subunits lead to enhanced degradation, while conditions favoring the presence of intact 70S ribosomes prevent or reduce breakdown (Zundel et al., 2009). Understanding the physiological conditions triggering these potential new functions of Era in ribosome homeostasis remains to be investigated.
Functional interplay between Era and YjeQ
Prior genetic experiments suggested functional interactions between Era and other assembly factors. For example, overexpression of Era suppressed the ribosome assembly defects in a ΔrbfA strain (Inoue et al., 2003), and overexpression of KsgA, which methylates residues in h45, suppressed the cold-sensitive phenotype of Era E200K (Lu and Inouye, 1998). Although these factors are thought to bind at non-overlapping sites on the 30S subunit, (Datta et al., 2007; Sharma et al., 2005), these results suggested that Era could facilitate the function of RbgA or KsgA and potentially substitute for them.
The present study investigates the functional interplay between Era and YjeQ and extends the work of Campbell and Brown (Campbell and Brown, 2008), who reported that Era overexpression increases polysome count and ameliorates the growth defect of a yjeQ null strain. YjeQ is thought to act during 30S subunit assembly by aiding in folding of helix 44 and decoding center (Guo et al., 2011; Jomaa et al., 2011a; Jomaa et al., 2011b; Lopez-Alonso et al., 2017; Razi et al., 2017). Our work suggests that Era has the opposite effect on mature ribosomes, as it appears to promote unfolding of helix 44 during the Era-dependent subunit splitting reaction (Figure 6). This result implies that Era binds to the immature 30S subunit independently from YjeQ. However, it remains unclear from this data how Era over-expression compensates for YjeQ function.
Role of Era in processing and folding of the rRNA
Given that Era recognizes the 1531AUCACCUCC1539 sequence, which is close to the mature 3’ end of 16S rRNA (Ji, 2016; Tu et al., 2009), Era has also been implicated in rRNA processing regulation. In these models, it is suggested that Era binding to this sequence could induce a conformational change in the 17S rRNA that promotes auto-cleavage or exposes the 3’ end of the 17S rRNA to RNases (Inoue et al., 2003). Alternatively, crystallography studies (Ji, 2016; Tu et al., 2009) propose that Era binding actually protects the rRNA from premature cleavage by RNAses during the ribosome assembly process. Our finding that Era depleted cells have higher ratios of 17S rRNA molecules containing the 5’ precursor sequence but not the 3’ sequence (Supplemental results) is consistent with Era playing a protective role by ensuring that the processing of the 3’ end does not occur prematurely. This putative protective role is also consistent with a recent model (Ghosal et al., 2018). proposing that the endoribonuclease YbeY forms a complex with Era to guide accurate RNAse-mediated cleavage of the terminal 33 nucleotides at the 3’ end of the 17S rRNA.
Overall, this study found that folding of helices 23 and 24 in the platform region of the 30S subunit directly or indirectly relies on Era. In the absence of this factor, particles skipped the folding of these two helices and were re-routed in their folding pathway. The assembling particles did not follow a sequential (from 5’ to 3’) folding and all three major domains of the 16S rRNA co-matured. In addition, we found that treatment of mature 30S subunits with Era destabilizes functionally essential regions of the 30S subunit. Further investigations in this newly discovered capacity of Era will unravel the putative role of this essential protein factor in mechanisms of ribosome homeostasis, including the reactivation of hibernating ribosomes or the triggering of ribosome degradation.
STAR*METHODS
Detailed methods are provided in the online version of this paper.
AUTHOR CONTRIBUTIONS
A.R. designed cryo-EM experiments, performed cryo-EM sample preparation, EM data collection and image analysis. J.D. performed the qMS experiments. Y.H. performed footprinting experiments, D.J. performed MST and 70S dissociation experiments. B.T. obtained the Era depleted strain. K.B. designed and implemented strategies for cryo-EM data collection in the Titan Krios TEM (FEMR-McGill). N.J performed qPCR analysis. J.G and J.V. assisted with designing image processing approaches. A.G. performed model building of the atomic models. R.B, J.W, S.W and J.O. designed and supervised the study. A.R. and J.O wrote the first draft of the manuscript and all authors contributed to editing.
DECLARATION OF INTEREST
The authors declare no conflict of interests.
STAR*METHODS KEY RESOURCES TABLE
CONTACT FOR REAGENT AND RESOURCE SHARING
Further information and requests for resources and reagents should be directed to and will be fulfilled by the Lead Contact, Joaquin Ortega (joaquin.ortega{at}mcgill.ca).
EXPERIMENTAL MODEL AND SUBJECT DETAILS
E. coli depletion strain and the strain for overexpression of Era were grown as noted in the STAR Methods section.
METHOD DETAILS
Cell strains and protein overexpression clones
The parental E. coli K-12 (BW25113) strain was obtained from the Keio collection, a set of E. coli K-12 in-frame, single gene knockout mutants (Baba et al., 2006).
The pET15b-era plasmids used for overexpression of Era were produced as described (Thurlow et al., 2016). The pDEST17-yjeQ plasmid used to overexpress YjeQ protein with an amino-terminal His6 tag cleavable by tobacco etch virus (TEV) protease was generated as described previously (Daigle et al., 2002).
Protein expression and purification
Overexpression and purification of Era (Thurlow et al., 2016) and YjeQ (Razi et al., 2017) proteins was done as previously described.
Creation of the Era-depleted strain
To generate the essential era gene depletion strain in the BW25113 E. coli background, we used the previously described pBS-araBADflankkan plasmid (Campbell and Brown, 2002) and the temperature sensitive pSim6 plasmid (Datta et al., 2006) for insertion of era at the araBAD locus and recombination into the chromosome, respectively. PCR amplification of the era gene was performed with the Era_up-R and Era_down-F oligonucleotides using the previously described pET15b-era plasmid (Thurlow et al., 2016) as a template for amplification. The amplified product was cloned into the PmeI site of the pBS-araBADflankkan and the resulting plasmid with era in the forward orientation with respect to the araBAD promoter was sequenced and named “pBS-araBADflankerakan”. The era knockout cassette was generated by PCR amplification of pSET152 (Bierman et al., 1992) with the Era_Apra-F and Era_Apra-R oligonucleotides. This generated an approximately 1100 bp product that contained the apramycinr cassette flanked by 50 bp of the upstream and downstream sequences of the native era gene.
The precise deletion of era was carried out as described by (Datsenko and Wanner, 2000; Link et al., 1997). pBS-araBADflankerakan was double digested with NotI and PsiI resulting in an approximately 3,200–bp and 2,600-bp product. The digestion reaction was resolved in a 1% agarose gel and the 3.2 kb product containing the era gene flanked by homologous regions to the araBAD promoter was excised and gel purified using the QIAquick gel extraction kit (Qiagen). Approximately 100 ng of this product was used to transform BW25113-pSim6 competent cells using electroporation and cells were plated on LB-agar containing 50 μg/ml kanamycin at 37 °C overnight to select for integrants at araBAD and facilitate curing of the temperature-sensitive pSim6 plasmid. To screen for strains in which the araBAD genes had been replaced by era, genomic DNA was isolated from the clones and used as a template for PCR amplification with the Era_down-F and Ara_up-R oligonucleotides (Figure S1A; top panel). A second round of PCR screening was performed using the Ara_int-F and Kan_int-R oligonucelotides (Figure S1A; bottom panel). A strain positive for chromosomal integration was selected and named “araBAD-era”. The era gene deletion protocol was conducted by transforming approximately 100 ng of the era knockout cassette using electroporation into araBAD-era-pSim6 cells followed by plating onto LB-agar containing 50 μg/ml kanamycin and 100 μg/ml apramycin and overnight incubation at 37 °C to select for integrants at the era locus and enable curing of the pSim6 plasmid. Genomic DNA was isolated from clones and used a template for PCR amplification using the EraKO_confirm-R and Apra_int-F oligonucleotides (Figure S1B; top panel) and the Apra_int-R and EraKO_confirm-F oligonucleotides (Figure S1B; bottom panel) were used to confirm the deletion of era. The resulting strain with genotype araBAD::era-kanr, era::aprr was called “Era-depleted”.
Strain growth experiments
To obtain the growth curves for the parental and Era-depleted strains, the cultures were grown overnight in LB media at 37 °C with shaking at 225 rpm in an Excella E24 incubator (New Brunswick). In the case of the Era-depleted strain, the LB media was supplemented with 1% arabinose. The overnight cultures were diluted 1/10,000 with LB media to a final volume of 100 μL in a 96-well plate with fresh LB media and the Era-depleted strain was grown in either the presence or absence of 1% arabinose. Cultures were incubated at either 37°C or 15°C with shaking in a Tecan Sunrise™ Plate Reader for either 24 or 72 hours, respectively. Culture density was monitored by measuring the optical density at 600 nm (OD600) every ten minutes during the time course of the experiment. Optical density was plotted over time (minutes) to show the growth curve for each strain at both 37 °C and 15 °C. The experiment was performed with five replicates.
Dilution plating experiments were performed by inoculating 0.5 mL of a saturated overnight culture in 50 mL of fresh LB media. Cultures were grown at 37°C with shaking until an OD600 of 0.2. Then, serial dilutions were made in 10-fold increments, and 5 μL of each dilution was immediately spotted onto LB agar plates with and without 1% arabinose and incubated at 37°C. The plates were incubated until isolated colonies of the parental strain reached ~2 mm in diameter.
Purification of ribosomal particles from parental and Era-depleted strain
Purification of mature 30S subunits was done from the parental E. coli K-12 (BW25113) strain after 1 L of LB media was inoculated with 10 mL of saturated overnight culture and grown to an OD600 of 0.2. Cultures were then cooled down to 4 °C and purification of the mature 30S subunits that were used in the cryo-EM experiments was done as previously described (Razi et al., 2017). In the case of the 30S subunits and 70S ribosomes purified under ‘low salt’ conditions for mass spectrometry, we used a previously published protocol (Leong et al., 2013), but all buffers A to F contained only 60 mM NH4Cl. In addition, the salt wash performed with buffer C was omitted.
In the case of the 30SEra-depleted particles and 70S ribosomes from Era-depleted strain, overnight cultures of this strain were grown at 37 °C with shaking at 225 rpm in LB media containing 1% arabinose, 100 μg/ml apramycin and 50 μg/ml kanamycin. To initiate depletion, cells from saturated overnight cultures were pelleted by centrifugation at 12,000g in a microcentrifuge and all arabinose containing media was removed. Cells were then diluted to OD600 of 0.02 in LB media containing 100 μg/ml apramycin and 50 μg/ml kanamycin and grown at 37 °C with agitation until they reached a doubling time of ~150 minutes. Cells were not allowed to grow beyond an OD600 of 0.2, thus if at this point cells were still exhibiting doubling times <150 min, then the culture was diluted again to OD600 = 0.02 into pre-warmed LB media with the same apramycin and kanamycin but without arabinose. Typically, two cycles of growth dilution were required before the cells reached ~150 min doubling time and then cultures were used to inoculate 4 liters of pre-warmed media to an OD600 of 0.02 and cells were grown with agitation until they reached an OD600 of 0.2. Full depletion of the Era protein was obtained in cells with a doubling time of 225 - 275 min. At that point, cells were harvested for purification of 30SEra-depleted particles and 70S ribosomes. To purify these particles, we used a similar protocol using ultracentrifugation over sucrose gradients as previously described (Leong et al., 2013). However, all buffers A to F contained only 60 mM NH4Cl. In addition, the salt wash performed with buffer C was omitted. This purified 30SEra-depleted particles and 70S ribosomes were used both for cryo-EM and mass spectrometry experiments. The calculation of the proportion of free 30S subunits in the Era-depletion strain from the sucrose gradient was done as previously described (Thurlow et al., 2016).
Ribosomal RNA Analysis of Era-depleted and parental strains by qPCR
Quantitative real time PCR (qPCR) was carried out using total RNA isolated from the parental and Era-depleted strain (grown under depletion conditions). The rRNA from each sample was purified using the RNeasy mini kit (Qiagen) according to the manufacturer’s protocol. RNA concentration in the sample was then measured by A260, where 1 absorbance unit is equivalent to 40 μg/mL of RNA. cDNA synthesis was carried out using 100ng of random hexamer primers and 10 ng of total RNA with Superscript III reverse transcriptase (Invitrogen) by following manufacturer protocol. cDNA was amplified by primer set P1, P2 and P3. ΔCt values for P2 and P3 oligo sets amplification for both wild type and Era-depleted strains were calculated against total 16S rRNA fragment measured by P1 set of oligos amplification. ΔΔCt was calculated for ΔCt(Era-depleted)-ΔCt(wild type) and fold expression was calculated by 2(-ΔΔCt). Standard deviations were calculated as described in manufacturer protocol of applied biosystem.
Quantitative mass spectrometry
Performing the qMS analysis of the ribosomal particles purified from the Era depleted and parental strains required to generate 15N-labeled isotopic spikes. Whole cell lysates spikes were generated by growing strain JD0189 (E. coli NCM3722 (Brown and Jun, 2015)) to OD600 0.4 in 15N-labeled minimal media at 37 °C as described previously (Davis et al., 2016). Cells were pelleted and resuspended in 50 mM Tris, 100 mM NH4Cl, 10 mM MgCl2 pH 7.8 to a concentration of 3.0 OD600 units/mL, which corresponds to ~0.05 μM ribosomes, assuming 5×108 cells/OD600/mL; 20,000 ribosomes/cell. 15N-labeled 70S particles spikes were generated by growing strain JD0189 to OD600 0.7 in 15N-labeled media as described above. Cells were lysed, and 70S particles were purified on a 10%-40% sucrose gradient as described (Davis et al., 2016). Fractions bearing monosomes or polysomes were pooled and saved at −80C at 0.055 μM.
To generate the tryptic peptides particles were isolated as described above and concentrated to 0.5 μM. To each sample (10 pmols), an equimolar 15N-labeled spike sample (either purified ribosomal particles or lysate bearing ~10 pmols of ribosomes) was added, mixed, and trichloroacetic acid (TCA) was added to 13% final concentration. After overnight precipitation at 4 °C, pellets were sequentially washed with 10% TCA, 100% Acetone and were dried before they were resuspended in 40 μL buffer B (100 mM NH4CO3, 5% acetonitrile, 5 mM dithiothreitol) as described (Jomaa et al., 2014). After reduction for 10 minutes at 65 °C, cysteines were alkylated by addition of iodoacetamide to 10 mM and incubation at 30 °C for 30 mins. Then, 0.2 μg trypsin was added, and protein digestion proceeded at 37 °C overnight. Tryptic peptides were purified on C18 PepClean columns, and ~1 μg of peptides was mixed with 500 fmol iRT retention time standards (Pierce) and injected onto the LC/MS.
To perform the qMS peptides were trapped on a ChomXP C18 cHiPLC column (Sciex) and resolved on a 15 cm ChromXP C18 cHiPLC analytical column using a 120 minute 5-35% linear acetonitrile gradient with a flowrate of 300 nL/min. Data was acquired in replicate with either data-dependent acquisitions or in SWATH data-independent acquisition (DIA) mode. Briefly, data-dependent acquisitions included one MS1 scan (200 msec accumulation time) followed by 30 MS2 scans (100 msec accumulation time). The SWATH DIA method consisted of one MS1 scan (200 msec accumulation time) followed by 32 MS2 scans (25 m/z wide, 100 msec accumulation time) covering the range 400-1200.
To analyze the abundance of the r-proteins in the ribosomal particles, DDA datasets were searched with comet (Eng et al., 2013), peptide-spectra matches (PSM) were scored with PeptideProphet (Deutsch et al., 2010) and scored PSMs were combined with iProphet (Shteynberg et al., 2011). A consensus spectral library was generated using Spectrast (Lam et al., 2007). Using this spectral library, a target list bearing 14N- and 15N-labeled precursor and product ions corresponding to ribosomal proteins of interest was generated using Skyline (MacLean et al., 2010), and ion chromatograms were extracted in regions of the chromatogram near the predicted elution time as determined using the iRT standards (Escher et al., 2012). Extracted ion chromatograms were filtered for interfering ions at both the MS1 and MS2 level, and relative peptide abundance was calculated as 14N_total_area/15N_total_area. For each sample and for each protein, the median peptide abundance ratio was then calculated, and these values were clustered across both samples and proteins using the ward linkage method and the Euclidean distance metric (Sturn et al., 2002). Non-ribosomal proteins were analyzed as described using a spectral library focused on assembly co-factors (Davis, Williamson Manuscript in preparation) (Davis et al., 2016).
In vivo DMS footprinting experiments
To prepare the cells for in vivo DMS footprinting, Era-depleted cells were grown overnight in LB supplemented with apramycin (100 μg/mL), kanamycin (50 μg /mL) and 1% arabinose at 37 °C with shaking at 200 rpm. A 10-mL aliquot of this overnight culture was collected as the ‘Era pre’ sample to be used for in vivo DMS footprinting (see below). Fresh LB medium (150 mL) with apramycin (100 μg/mL) and kanamycin (50 μg/mL) was inoculated with 150 μL overnight culture to achieve an OD600 = 0.02. The culture was grown at 37 °C until the doubling time reached 100-150 minutes. This culture was then used to inoculate fresh LB media without antibiotic (initial OD600 was 0.02). The culture was grown until the doubling time reached 200-250 minutes, when two 50 mL aliquots were removed as the Era depleted (Era-) samples. A portion of the Era depleted culture was sub-cultured to and OD600 of 0.02 into LB media with apramycin (100 μg/mL), kanamycin (50 μg/mL) and 1% arabinose to induce Era expression, and this time was recorded as the start of Era re-expression. 50 mL of samples were collected for analysis and DMS footprinting at 1, 2, 3, 4 and 4.5 h after Era re-expression. As a control for second site suppressors, a portion of the Era-culture was rediluted to an OD600 of 0.02 in LB without antibiotics or arabinose. The cultures containing arabinose had a shorter doubling time than the control sample lacking arabinose. During the entire procedure, the growth of all cultures was measured every hour to avoid exceeding an OD600 = 0.2, 0.2, at which point cultures were diluted to OD600 = 0.02 with fresh medium.
The in vivo DMS footprinting was carried out on 50-mL cultures, OD600 = 0.2, by adding 5 mL 20% (v/v) dimethyl sulfate in ethanol at room temperature for 30 s. The methylation reaction was quenched with 25 mL of ice-cold 1.4 M β-mercaptoethanol and 25 mL of water-saturated isoamyl alcohol for 30 s on ice. The cells were collected at 4,000 rpm (3,315 x g) for 10 min using a JS-5.3 rotor (Beckman Coulter). The cell pellets were resuspended twice in the same volume of 0.7 M β-mercaptoethanol and harvested by centrifugation after each step. The washed pellets were stored at −80 °C prior to RNA extraction.
Total RNA was extracted from each cell pellet using the RNeasy mini-prep (Qiagen), and the final RNA concentration was determined from the UV absorption. The DMS modification pattern was analyzed by reverse transcription as previously described (Hao et al., 2018; Hao and Kieft, 2014). For each reaction, 2 μg total RNA was annealed with 2 pmol (30,000 cpm) 32P-labeled primer (primer 46 or primer 812) at 65 °C for 3 min before extension with Superscript III (Thermo Scientific) for 60 min at 55 °C. Sequencing lanes were normalized to the total intensity in each lane, excluding the unextended primer and the full-length cDNA, using ImageQuant software. This was followed by background subtraction of the control lanes (– DMS) in Microsoft Excel.
70S dissociation experiments
The parental E. coli K-12 strain (BW25113) was used for purification of the 70S ribosomes used in these experiments. Typically, 3 L of LB media were inoculated with 10 mL each of saturated overnight culture and grown to an OD600 of 0.6. Cells were harvested by centrifugation at 3,700 g for 15 min. Cell pellets were resuspended in 7 mL of buffer A (20 mM TrisHCl at pH 7.5, 10 mM magnesium acetate, 100 mM NH4Cl, 0.5 mM EDTA, 3 mM 2-mercaptoethanol, and a protease inhibitor mixture (cOmplete Protease Inhibitor Mixture Tablets; Roche) and DNaseI (Roche). Each of the subsequent steps was performed at 4 °C. The cell suspension was passed through a French pressure cell at 1,400 kg/cm2 three consecutive times to lyse the cells. The lysate was spun at 59,000g for 30 min to clear cell debris. Resulting supernatant was layered over a sucrose cushion of equal volume composed of 30% sucrose in buffer B (20 mM TrisHCl pH 7.5, 10 mM magnesium acetate, 500 mM NH4Cl, 0.5 mM EDTA, and 3 mM 2-mecaptoethanol), and then spun down for 4.5 h at 321,000g. The pellet was resuspended in buffer C containing 10 mM TrisHCl pH 7.5, 10 mM magnesium acetate, 500 mM NH4Cl, 0.5 mM EDTA and 3 mM 2-mecaptoethanol and then spun for 16 h at 100,000g. The washed ribosome pellet was resuspended in buffer E containing 10 mM Tris·HCl pH 7.5, 10 mM magnesium acetate, 60 mM NH4Cl, and 3 mM 2-mecaptoethanol, which caused subunits to be associated. Approximately 120 A260 units of resuspended crude ribosomes were then applied to 34 mL of 10–30% (wt/vol) sucrose gradients prepared with buffer E. The gradients were centrifuged for 16 h at 40,000g on a Beckman Coulter SW32 Ti rotor. Gradients were fractionated using a Brandel fractionator apparatus and an AKTA Prime FPLC system (GE Healthcare). The elution profile was monitored by UV absorbance at A254, and fractions corresponding to the 70S subunit peak were pooled and spin down for another 4.5 h at 321,000g on a Beckman SW32 Ti rotor. The pellet was resuspended in Buffer E.
To perform the 70S dissociation experiment purified Era was first passed through a Superdex 200 size-exclusion column (GE Healthcare) equilibrated with buffer containing 50mM TrisHCl pH 8.0. To assemble the dissociation reaction 1uM 70S ribosomes were incubated with either 2- or 5-fold molar excess of Era. Reactions had a total volume of in a 120 μL and were assembled in buffer containing 20mM TrisHCl pH 7.5, 20mM magnesium acetate, 30mM potassium chloride, 4mM 2-mecaptoethanol. Where indicated we added up to 1 mM of nucleotide (GTP/GDP/GDPPNP). After 15-minute incubation at 37°C each reaction was loaded onto 34 mL 10-30% (wt/vol) sucrose gradients prepared with buffer E and centrifuged for 16 h at 40,000g on a Beckman Coulter SW32 Ti rotor. Gradients were fractionated using a Brandel fractionator apparatus and an AKTA Prime FPLC system (GE Healthcare). The elution profile was monitored by UV absorbance at A254.
Microscale thermophoresis
Mature 30S subunits were fluorescently labeled as described (Thurlow et al., 2016). Prior to each MST experiment, all samples were centrifuged at 14000g for 10 min to remove any aggregates. All reaction and titrations series were prepared in MST buffer containing 20 mM Tris-HCl pH 7.5, 150 mM NaCl, 10 mM MgCl2, 1 mM DTT, 0.05% Tween-20, 0.4 mg/ml BSA and were incubated in in 0.5 ml Protein LoBind eppendorf tubes. Prior to performing the MST experiment, 0.5 μM fluorescently labeled mature 30S subunits were incubated with either 5 μM or 10 μM Era. GDPPNP was added to a final concentration of 1mM and the assembly reaction was incubated for 15 minutes at room temperature. A 1:1 serial dilution of non-labelled YjeQ was then prepared in MST buffer starting at 4 μM. The 30S+Era reaction mixtures were then diluted with MST buffer containing 1mM GDPPNP until the 30S subunits reached a concentration of 40nM. For the titration assay, ten microliters of the corresponding serial dilution of the non-labeled YjeQ was mixed with 10 μl of the fluorescently labeled 30S subunit pre-bound with Era (or without Era for the negative control). Titration reactions were then incubated for 10 min at room temperature loaded into premium capillaries (NanoTemper Technologies) and MST analysis was performed using the Monolith NT.115 (NanoTemper Technologies) at ambient temperature. An LED power of 100% and an MST power of 20–60% were used during MST readings. The resulting binding curves were obtained by plotting the normalized fluorescence (Fnorm (‰) = F1 /F0) versus the logarithm of YjeQ concentration. Kds were calculated using the NanoTemper MO Affinity Analysis software. Experiments were performed in triplicates.
Cryo-electron microscopy
The 30SEra-depleted particles were prepared for imaging with cryo-EM by preparing a dilution of the particles in buffer E (10mM Tris–HCl at pH 7.5, 10mM magnesium acetate, 60mM NH4Cl and 3mM 2-mercaptoethanol) to a concentration of 30nM that was applied directly to the grid and immediately right after the dilution step. The reactions containing 30S and Era for cryo-EM experiments were prepared as followed. A 20 μL reaction was first prepared in buffer E containing mature 30S subunits (0.5 μM) and Era protein (20 μM). GDPPNP was added to this reaction to a concentration of 2 mM. After the reaction was incubated at 37 °C for 15 min, the reaction was diluted 5-fold in buffer E containing GDPPNP at 2 mM and free Era protein at 4 μM and immediately applied to the EM grid. Finally, in the reaction containing mature 30S, Era and YjeQ for cryo-EM experiments, these components were added to final concentrations of 2 μM, 20 μM and 3.5 μM, respectively. GDPPNP was added to this reaction to a concentration of 2 mM. After the reaction was incubated at 37 °C for 15 min, the assembly reaction was diluted 10-fold in buffer E containing GDPPNP at 2 mM and immediately applied to the EM grid.
In all samples a volume of 3.6 μl of the diluted sample was applied to holey carbon grids (c-flat CF-2/2-2C-T) with an additional layer of continuous thin carbon (5-10nm). Before the sample was applied, grids were glow discharged in air at 5 mA for 15 seconds. Vitrification of samples was performed in a Vitrobot (Thermo Fisher Scientific Inc.) by blotting the grids once for 3 seconds and with a blot force +1 before they were plunged into liquid ethane. The Vitrobot was set at 25 °C and 100% relative humidity.
Automated data acquisition was performed using EPU software at FEMR-McGill using a Titan Krios microscope at 300 kV equipped with a Falcon II direct electron detector (Thermo Fisher Scientific Inc.). Movies for the 30SEra-depleted particles, Era-treated 30S particles and Era+YjeQ-treated 30S particles were collected with a total dose of 35, 46 and 28 e-/Å2, respectively. All datasets were collected as movies with seven frames acquired in 1 second exposure at a magnification of 75,000x, producing images with a calibrated pixel size of 1.073 Å. The nominal defocus range used during data collection was between −1.25 to −2.75 μm.
Image processing
Motion correction and contrast transfer function (CTF) estimation for each collected movie was done with MotionCor2 (Zheng et al., 2017) and Gctf (Zhang, 2016) programs, respectively. From here all processing was done with Relion 2.1 program (Kimanius et al., 2016). Particle images after the autopicking process were subjected to reference-free 2D classification to produce a ‘clean’ dataset. The selected particles were subsequently used for hierarchical 3D classification approaches. The initial 3D reference used for these classifications was either a 60 Å low pass filtered map of the mature 30S subunit, the intermediate cryo-EM maps obtained during classification or maps obtained by ab initio approaches. The ab initio methodologies we used to generate these initial maps were random sample consensus (RANSAC) as implemented in Scipion (Vargas et al., 2014) and common lines as implemented in EMAN2 (Tang et al., 2007). In the case of the 3D classifications of the datasets for the 30SEra-depleted particles and the Era-treated 30S particles no mask was used. However, masks created from the mature structure or intermediate maps obtained during the classification were used in the case of the Era+YjeQ-treated 30S particles. All masks were obtained with ‘relion_mask_create’ command using an initial threshold for binarization of 0.01, extension of the binary mask by two pixels and creating a soft-edges with a width of two pixels. Classes obtained at the end of each classification approach were inspected visually and those deemed to represent the same structures were grouped for refinement. A soft-mask was applied in all refinements.
To improve the details on the density potentially representing Era in the Era-treated 30S particles and Era+YjeQ-treated 30S particles, the corresponding datasets were subjected to focus classification with subtraction of the residual signal using Relion (Scheres, 2012) following an approach previously described (Bai et al., 2015).
Sharpening of the cryo-EM maps was done by applying a negative B-factor estimated using automated procedures (Rosenthal and Henderson, 2003). Local resolution analysis of the structures was also done using Relion procedures (Kimanius et al., 2016).
Map analysis and Atomic model building
Visualization of the cryo-EM maps was done using Chimera (Pettersen et al., 2004). Before initiating high-resolution model building of the cryo-EM map obtained for the 30SEra-depleted particle (class P), we maximize detail and connectivity of this map using the automatic sharpening tool phenix.auto_sharpen (Terwilliger et al., 2018), which is available as part of the PHENIX software suite (Adams et al., 2010). The starting point for the modeling of this map was the atomic model of the mature 30S subunit (PDB ID 2AVY). This initial model was first fit into the density as a rigid body using Chimera (Pettersen et al., 2004) and the final model was built with successive rounds of real space refinement in Phenix (Afonine et al., 2018) and manual model building in Coot (Emsley and Cowtan, 2004; Emsley et al., 2010). Areas of the map not exhibiting corresponding density were deleted and not incorporated into the models.
Figures for this manuscript were prepared using Pymol program (The PyMOL Molecular Graphics System, Version 1.2r3pre, Schrödinger, LLC), UCSF Chimera and Chimera X (Pettersen et al., 2004).
QUANTIFICATION AND STATISTICAL ANALYSIS
Quantitation of mass spectrometry data detailed above. Statistical values, where calculated, can be found in the Figure legends.
DATA AND SOFTWARE AVAILABIILITY
All maps are deposited at EMDB as noted in the Key Resources Table.
ACKNOWLEDGEMENTS
We are grateful to Drs. Eric Brown and Jean Philippe Cote for their technical assistance in the production of the Era depleted E. coli strain. We thank Drs. Kelly Sears, Mike Strauss and other staff members of the Facility for Electron Microscopy Research (FEMR) at McGill University for help in microscope operation and data collection. We acknowledge Jingyu Sun for providing purified Era for MST experiments and Clara Ortega for assistance with graphic design. This work was supported by grants from the Canadian Institutes of Health Research (PJT-153044) to J.O and NIH grant R01GM110248 from NIGMS to RAB. Titan Krios cryo-EM data were collected at FEMR (McGill). FEMR is supported by the Canadian Foundation for Innovation and Quebec government.