The molecular choreography of IRF4 and IRF8 with immune system partners.

The transcription factors IRF4 and IRF8 represent immune-specific members of the interferon regulatory family. They play major roles in controlling the development and functioning of innate and adaptive cells. Genes encoding these factors appear to have been coopted by the immune system via gene duplication and divergence of regulatory and protein coding sequences to enable the acquisition of unique molecular properties and functions. Unlike other members of the IRF family, IRF4 and IRF8 do not activate transcription of Type 1 interferon genes or positively regulate interferon-induced gene expression. Instead, they bind to unusual composite Ets-IRF or AP-1-IRF elements with specific Ets or AP-1 family transcription factors, respectively, and regulate the expression of diverse sets of immune response genes in innate as well as adaptive cells.

A genomic regulatory element that directs assembly and function of immune-specific AP-1-IRF complexes.

Interferon regulatory factor 4 (IRF4) and IRF8 regulate B, T, macrophage, and dendritic cell differentiation. They are recruited to cis-regulatory Ets-IRF composite elements by PU.1 or Spi-B. How these IRFs target genes in most T cells is enigmatic given the absence of specific Ets partners. Chromatin immunoprecipitation sequencing in T helper 17 (T(H)17) cells reveals that IRF4 targets sequences enriched for activating protein 1 (AP-1)-IRF composite elements (AICEs) that are co-bound by BATF, an AP-1 factor required for T(H)17, B, and dendritic cell differentiation. IRF4 and BATF bind cooperatively to structurally divergent AICEs to promote gene activation and T(H)17 differentiation. The AICE motif directs assembly of IRF4 or IRF8 with BATF heterodimers and is also used in T(H)2, B, and dendritic cells. This genomic regulatory element and cognate factors appear to have evolved to integrate diverse immunomodulatory signals.

Principles of dimer-specific gene regulation revealed by a comprehensive characterization of NF-κB family DNA binding.

The unique DNA-binding properties of distinct NF-κB dimers influence the selective regulation of NF-κB target genes. To more thoroughly investigate these dimer-specific differences, we combined protein-binding microarrays and surface plasmon resonance to evaluate DNA sites recognized by eight different NF-κB dimers. We observed three distinct binding-specificity classes and clarified mechanisms by which dimers might regulate distinct sets of genes. We identified many new nontraditional NF-κB binding site (κB site) sequences and highlight the plasticity of NF-κB dimers in recognizing κB sites with a single consensus half-site. This study provides a database that can be used in efforts to identify NF-κB target sites and uncover gene regulatory circuitry.

Phylogeny as a guide to structure and function of membrane transport proteins.

Protein phylogeny, based on primary amino acid sequence relatedness, reflects the evolutionary process and therefore provides a guide to structure, mechanism and function. Any two proteins that are related by common descent are expected to exhibit similar structures and functions to a degree proportional to the degree of their sequence similarity; but two independently evolving proteins should not. This principle provides the impetus to define protein phylogenetic relationships and interrelate families when possible. In this mini-review, we summarize the computational approaches and criteria we use to establish common evolutionary origin. We apply these tools to define distant superfamily relationships between several previously recognized transport protein families. In some cases, available structural and functional data are evaluated in order to substantiate our claim that molecular phylogeny provides a reliable guide to protein structure and function.

A transporter of Escherichia coli specific for L- and D-methionine is the prototype for a new family within the ABC superfamily.

An ABC-type transporter in Escherichia coli that transports both L- and D-methionine, but not other natural amino acids, was identified. This system is the first functionally characterized member of a novel family of bacterial permeases within the ABC superfamily. This family was designated the methionine uptake transporter (MUT) family (TC #3.A.1.23). The proteins that comprise the transporters of this family were analyzed phylogenetically, revealing the probable existence of several sequence-divergent primordial paralogues, no more than two of which have been transmitted to any currently sequenced organism. In addition, MetJ, the pleiotropic methionine repressor protein, was shown to negatively control expression of the operon encoding the ABC-type methionine uptake system. The identification of MetJ binding sites (in gram-negative bacteria) or S-boxes (in gram-positive bacteria) in the promoter regions of several MUT transporter-encoding operons suggests that many MUT family members transport organic sulfur compounds.

The multidrug/oligosaccharidyl-lipid/polysaccharide (MOP) exporter superfamily.

The multidrug/oligosaccharidyl-lipid/polysaccharide (MOP) exporter superfamily (TC #2.A.66) consists of four previously recognized families: (a) the ubiquitous multi-drug and toxin extrusion (MATE) family; (b) the prokaryotic polysaccharide transporter (PST) family; (c) the eukaryotic oligosaccharidyl-lipid flippase (OLF) family and (d) the bacterial mouse virulence factor family (MVF). Of these four families, only members of the MATE family have been shown to function mechanistically as secondary carriers, and no member of the MVF family has been shown to function as a transporter. Establishment of a common origin for the MATE, PST, OLF and MVF families suggests a common mechanism of action as secondary carriers catalyzing substrate/cation antiport. Most protein members of these four families exhibit 12 putative transmembrane alpha-helical segments (TMSs), and several have been shown to have arisen by an internal gene duplication event; topological variation is observed for some members of the superfamily. The PST family is more closely related to the MATE, OLF and MVF families than any of these latter three families are related to each other. This fact leads to the suggestion that primordial proteins most closely related to the PST family were the evolutionary precursors of all members of the MOP superfamily. Here, phylogenetic trees and average hydropathy, similarity and amphipathicity plots for members of the four families are derived and provide detailed evolutionary and structural information about these proteins. We show that each family exhibits unique characteristics. For example, the MATE and PST families are characterized by numerous paralogues within a single organism (58 paralogues of the MATE family are present in Arabidopsis thaliana), while the OLF family consists exclusively of orthologues, and the MVF family consists primarily of orthologues. Only in the PST family has extensive lateral transfer of the encoding genes occurred, and in this family as well as the MVF family, topological variation is a characteristic feature. The results serve to define a large superfamily of transporters that we predict function to export substrates using a monovalent cation antiport mechanism.

Bioinformatic analyses of the bacterial L-ascorbate phosphotransferase system permease family.

The tripartite L-ascorbate permease of Escherichia coli is the first functionally characterized member of a large family of enzyme II complexes (SgaTBA, encoding enzymes IIC, IIB and IIA) of the bacterial phosphotransferase system (PTS). We here report bioinformatic analyses of these proteins. Forty-five homologous systems from a wide variety of bacteria were identified, but no homologues were found in archaea or eukaryotes. These systems fell into five structural types: (1) IIC, IIB and IIA are encoded by distinct genes; (2) IIC and IIB are encoded by distinct genes, but the IIA-encoding gene is absent; (3) IIC and IIB are encoded by a fused gene, but IIA is a distinct gene product; (4) IIA and IIB are fused, but IIC is encoded by a distinct gene, and (5) IIC and IIB are encoded by distinct genes, but IIA is fused to a transcriptional regulator. Phylogenetic analyses revealed that gene fusion/splicing events have occurred repeatedly during the evolutionary divergence of family members, although no evidence for shuffling of constituents between systems was obtained. The SgaTBA family proved to be distantly related to the GatCBA family of PTS permeases, and this family was also analyzed. In contrast to the SgaTBA family, no gene splicing/fusion has occurred during the evolutionary divergence of GatCBA family members as each domain is always encoded by a distinct gene. However, GatC homologues were identified in organisms that lack other PTS proteins, suggesting a transport mechanism not coupled to substrate phosphorylation. Topological analyses suggest that in contrast to all other PTS permeases, IIC proteins of the Sga and Gat families exhibit 12 transmembrane alpha-helical segments and are distantly related to secondary carriers. Like many secondary carriers, GatC (IIC) homologues could be shown to have arisen by an ancient intragenic duplication event. These results suggest that the Sga and Gat families of PTS permeases comprise a small superfamily in which the transmembrane IIC domains evolved independently of all other known PTS permeases.