Type III secretion system


The type III secretion system is one of the bacterial secretion systems used by bacteria to secrete their effector proteins into the host's cells to promote virulence and colonisation. While the type III secretion system has been widely regarded as equivalent to the injectisome, many argue that the injectisome is only part of the type III secretion system, which also include structures like the flagellar export apparatus. The T3SS is a needle-like protein complex found in several species of pathogenic gram-negative bacteria.

Overview

The term 'Type III secretion system' was coined in 1993. This secretion system is distinguished from at least five other secretion systems found in gram-negative bacteria. Many animal and plant associated bacteria possess similar T3SSs. These T3SSs are similar as a result of convergent evolution and phylogenetic analysis supports a model in which gram-negative bacteria can transfer the T3SS gene cassette horizontally to other species. Some of the most researched T3SSs are from species of:
  • Shigella,
  • Salmonella,
  • Escherichia coli,
  • Vibrio,
  • Burkholderia,
  • Yersinia,
  • Chlamydia,
  • Pseudomonas and the
  • Plant pathogens such as Erwinia, Ralstonia and Xanthomonas, and the plant symbiont Rhizobium.
The T3SS is composed of approximately 30 different proteins, making it one of the most complex secretion systems. Its structure shows many similarities with bacterial flagella. Some of the proteins participating in T3SS share amino-acid sequence homology to flagellar proteins. Some of the bacteria possessing a T3SS have flagella as well and are motile, and some do not. Technically speaking, type III secretion is used both for secreting infection-related proteins and flagellar components. However, the term "type III secretion" is used mainly in relation to the infection apparatus. The bacterial flagellum shares a common ancestor with the type III secretion system.
T3SSs are essential for the pathogenicity of many pathogenic bacteria. Defects in the T3SS may render a bacterium non-pathogenic. It has been suggested that some non-invasive strains of gram-negative bacteria have lost the T3SS because the energetically costly system is no longer of use. Although traditional antibiotics were effective against these bacteria in the past, antibiotic-resistant strains constantly emerge. Understanding the way the T3SS works and developing drugs targeting it specifically have become an important goal of many research groups around the world since the late 1990s.

Structure

The hallmark of T3SS is the needle or the T3SS apparatus. Bacterial proteins that need to be secreted pass from the bacterial cytoplasm through the needle directly into the host cytoplasm. Three membranes separate the two cytoplasms: the double membranes of the Gram-negative bacterium and the eukaryotic membrane. The needle provides a smooth passage through those highly selective and almost impermeable membranes. A single bacterium can have several hundred needle complexes spread across its membrane. It has been proposed that the needle complex is a universal feature of all T3SSs of pathogenic bacteria.
The needle complex starts at the cytoplasm of the bacterium, crosses the two membranes and protrudes from the cell. The part anchored in the membrane is the base of the T3SS. The extracellular part is the needle. A so-called inner rod connects the needle to the base. The needle itself, although the biggest and most prominent part of the T3SS, is made out of many units of a single protein. The majority of the different T3SS proteins are therefore those that build the base and those that are secreted into the host. As mentioned above, the needle complex shares similarities with bacterial flagella. More specifically, the base of the needle complex is structurally very similar to the flagellar base; the needle itself is analogous to the flagellar hook, a structure connecting the base to the flagellar filament.
The base is composed of several circular rings and is the first structure that is built in a new needle complex. Once the base is completed, it serves as a secretion machine for the outer proteins. Once the whole complex is completed the system switches to secreting proteins that are intended to be delivered into host cells. The needle is presumed to be built from bottom to top; units of needle monomer protein pile upon each other, so that the unit at the tip of the needle is the last one added. The needle subunit is one of the smallest T3SS proteins, measuring at around 9 kDa. 100−150 subunits comprise each needle.
The T3SS needle measures around 60−80 nm in length and 8 nm in external width. It needs to have a minimal length so that other extracellular bacterial structures do not interfere with secretion. The hole of the needle has a 3 nm diameter. Most folded effector proteins are too large to pass through the needle opening, so most secreted proteins must pass through the needle unfolded, a task carried out by the ATPase at the base of the structure.

T3SS proteins

The T3SS proteins can be grouped into three categories:
  • Structural proteins: build the base, the inner rod and the needle.
  • Effector proteins: get secreted into the host cell and promote infection / suppress host cell defences.
  • Chaperones: bind effectors in the bacterial cytoplasm, protect them from aggregation and degradation and direct them towards the needle complex.
Most T3SS genes are laid out in operons. These operons are located on the bacterial chromosome in some species and on a dedicated plasmid in other species. Salmonella, for instance, has a chromosomal region in which most T3SS genes are gathered, the so-called Salmonella pathogenicity island. Shigella, on the other hand, has a large virulence plasmid on which all T3SS genes reside. It is important to note that many pathogenicity islands and plasmids contain elements that allow for frequent horizontal gene transfer of the island/plasmid to a new species.
Effector proteins that are to be secreted through the needle need to be recognized by the system, since they float in the cytoplasm together with thousands of other proteins. Recognition is done through a secretion signal—a short sequence of amino acids located at the beginning of the protein, that the needle complex is able to recognize. Unlike other secretion systems, the secretion signal of T3SS proteins is never cleaved off the protein.

Induction of secretion

Contact of the needle with a host cell triggers the T3SS to start secreting; not much is known about this trigger mechanism. Secretion can also be induced by lowering the concentration of calcium ions in the growth medium and by adding the aromatic dye Congo red to the growth medium, for instance. These methods and other are used in laboratories to artificially induce type III secretion.
Induction of secretion by external cues other than contact with host cells also takes place in vivo, in infected organisms. The bacteria sense such cues as temperature, pH, osmolarity and oxygen levels, and use them to "decide" whether to activate their T3SS. For instance, Salmonella can replicate and invade better in the ileum rather than in the cecum of animal intestine. The bacteria are able to know where they are thanks to the different ions present in these regions; the ileum contains formate and acetate, while the cecum does not. The bacteria sense these molecules, determine that they are at the ileum and activate their secretion machinery. Molecules present in the cecum, such as propionate and butyrate, provide a negative cue to the bacteria and inhibit secretion. Cholesterol, a lipid found in most eukaryotic cell membranes, is able to induce secretion in Shigella.
The external cues listed above either regulate secretion directly or through a genetic mechanism. Several transcription factors that regulate the expression of T3SS genes are known. Some of the chaperones that bind T3SS effectors also act as transcription factors. A feedback mechanism has been suggested: when the bacterium does not secrete, its effector proteins are bound to chaperones and float in the cytoplasm. When secretion starts, the chaperones detach from the effectors and the latter are secreted and leave the cell. The lone chaperones then act as transcription factors, binding to the genes encoding their effectors and inducing their transcription and thereby the production of more effectors.
Structures similar to Type3SS injectisomes have been proposed to rivet gram negative bacterial outer and inner membranes to help release outer membrane vesicles targeted to deliver bacterial secretions to eukaryotic host or other target cells in vivo.

T3SS-mediated infection

T3SS effectors enter the needle complex at the base and make their way inside the needle towards the host cell. The exact way in which effectors enter the host is mostly unknown. It has been previously suggested that the needle itself is capable of puncturing a hole in the host cell membrane; this theory has been refuted. It is now clear that some effectors, collectively named translocators, are secreted first and produce a pore or a channel in the host cell membrane, through which other effectors may enter. Mutated bacteria that lack translocators are able to secrete proteins but are not able to deliver them into host cells. In general each T3SS includes three translocators. Some translocators serve a double role; after they participate in pore formation they enter the cell and act as bona fide effectors.
T3SS effectors manipulate host cells in several ways. The most striking effect is the promoting of uptake of the bacterium by the host cell. Many bacteria possessing T3SSs must enter host cells in order to replicate and propagate infection. The effectors they inject into the host cell induce the host to engulf the bacterium and to practically "eat" it. In order for this to happen the bacterial effectors manipulate the actin polymerization machinery of the host cell. Actin is a component of the cytoskeleton and it also participates in motility and in changes in cell shape. Through its T3SS effectors the bacterium is able to utilize the host cell's own machinery for its own benefit. Once the bacterium has entered the cell it is able to secrete other effectors more easily and it can penetrate neighboring cells and quickly infect the whole tissue.
T3SS effectors have also been shown to tamper with the host's cell cycle and some of them are able to induce apoptosis. One of the most researched T3SS effector is IpaB from Shigella flexneri. It serves a double role, both as a translocator, creating a pore in the host cell membrane, and as an effector, exerting multiple detrimental effects on the host cell. It had been demonstrated that IpaB induces apoptosis in macrophages—cells of the animal immune system—after being engulfed by them. It was later shown that IpaB achieves this by interacting with caspase 1, a major regulatory protein in eukaryotic cells.
Another well characterized class of T3SS effectors are Transcription Activator-like effectors from Xanthomonas. When injected into plants, these proteins can enter the nucleus of the plant cell, bind plant promoter sequences, and activate transcription of plant genes that aid in bacterial infection. TAL effector-DNA recognition has recently been demonstrated to comprise a simple code and this has greatly improved the understanding of how these proteins can alter the transcription of genes in the host plant cells.