The Escherichia coli inducible lysine decarboxylase, LdcI/ CadA, together with the inner-membrane lysine-cadaverine antiporter, CadB, provide cells with protection against mild acidic conditions (pHB5). To gain a better understanding of the molecular processes underlying the acid stress response, the X-ray crystal structure of LdcI was determined. The structure revealed that the protein is an oligomer of five dimers that associate to form a decamer. Surprisingly, LdcI was found to co-crystallize with the stringent response effector molecule ppGpp, also known as the alarmone, with 10 ppGpp molecules in the decamer. ppGpp is known to mediate the stringent response, which occurs in response to nutrient deprivation. The alarmone strongly inhibited LdcI enzymatic activity. This inhibition is important for modulating the consumption of lysine in cells during acid stress under nutrient limiting conditions. Hence, our data provide direct evidence for a link between the bacterial acid stress and stringent responses.
ClpP is a highly conserved serine protease present in most bacterial species and in the mitochondria of mammalian cells. It forms a cylindrical tetradecameric complex arranged into two stacked heptamers. The two heptameric rings of ClpP enclose a roughly spherical proteolytic chamber of about 51 Å in diameter with 14 Ser-His-Asp proteolytic active sites. ClpP typically forms complexes with unfoldase chaperones of the AAA+ superfamily. Chaperones dock on one or both ends of the ClpP double ring cylindrical structure. Dynamics in the ClpP structure is critical for its function. Polypeptides targeted for degradation by ClpP are initially recognized by the AAA+ chaperones. Polypeptides are unfolded by the chaperones and then translocated through the ClpP axial pores, present on both ends of the ClpP cylinder, into the ClpP catalytic chamber. The axial pores of ClpP are gated by dynamic axial loops that restrict or allow substrate entry. As a processive protease, ClpP degrades substrates to generate peptides of about 7-8 residues. Based on structural, biochemical and theoretical studies, the exit of these polypeptides from the proteolytic chamber is proposed to be mediated by the dynamics of the ClpP oligomer. The ClpP cylinder has been found to exist in at least three conformations, extended, compact and compressed, that seem to represent different states of ClpP during its proteolytic functional cycle. In this review, we discuss the link between ClpP dynamics and its activity. We propose that such dynamics also exist in other cylindrical proteases such as HslV and the proteasome.
The inducible lysine decarboxylase LdcI is an important enterobacterial acid stress
response enzyme whereas LdcC is its close paralogue thought to play mainly a
metabolic role. A unique macromolecular cage formed by two decamers of the
Escherichia coli LdcI and five hexamers of the AAA+ ATPase RavA was shown
to counteract acid stress under starvation. Previously, we proposed a pseudoatomic
model of the LdcI-RavA cage based on its cryo-electron microscopy map and crystal
structures of an inactive LdcI decamer and a RavA monomer. We now present
cryo-electron microscopy 3D reconstructions of the E. coli LdcI and LdcC, and
an improved map of the LdcI bound to the LARA domain of RavA, at pH optimal for
their enzymatic activity. Comparison with each other and with available structures
uncovers differences between LdcI and LdcC explaining why only the acid stress
response enzyme is capable of binding RavA. We identify interdomain movements
associated with the pH-dependent enzyme activation and with the RavA binding.
Multiple sequence alignment coupled to a phylogenetic analysis reveals that certain
enterobacteria exert evolutionary pressure on the lysine decarboxylase towards the
cage-like assembly with RavA, implying that this complex may have an important
function under particular stress conditions.
A 3.3 MDa macromolecular cage between two Escherichia coli proteins with seemingly incompatible symmetries–the hexameric AAA+ ATPase RavA and the decameric inducible lysine decarboxylase LdcI–is reconstructed by cryo-electron microscopy to 11 Å resolution. Combined with a 7.5 Å resolution reconstruction of the minimal complex between LdcI and the LdcI-binding domain of RavA, and the previously solved crystal structures of the individual components, this work enables to build a reliable pseudoatomic model of this unusual architecture and to identify conformational rearrangements and specific elements essential for complex formation. The design of the cage created via lateral interactions between five RavA rings is unique for the diverse AAA+ ATPase superfamily.DOI:
http://dx.doi.org/10.7554/eLife.03653.001
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