Cortistatin is endogenous to the human intervertebral disc and exerts in vitro mitogenic effects on annulus cells and a downregulatory effect on TNF-α expression.

BACKGROUND CONTEXT: Cortistatin (CST) is a recently discovered cyclic neuropeptide with biologic anti-inflammatory properties relevant to disc degeneration. PURPOSE: To test whether CST is present in the disc tissue, whether its expression is influenced by tumor necrosis factor-α (TNF-α), and whether it influences cell proliferation. STUDY DESIGN: Institutional review board-approved study using immunohistochemistry on human disc tissue, in vitro annulus cultures to determine the effect of CST on cell proliferation, and the effect of TNF-α on CST gene expression. PATIENT SAMPLE: Discs from 12 subjects used for immunohistochemistry, four annulus specimens used for cell culture with proinflammatory cytokines, and 11 used for cell proliferation analyses. OUTCOME MEASURES: Immunohistochemical localization of CST, gene expression of CST, and cell proliferation analyses. METHODS: Immunohistochemistry localized CST in disc tissue. Microarray analysis measured CST gene expression. Human annulus cells were exposed to CST for proliferation tests or cultured for the effect of TNF-α on CST expression. Standard statistical analyses were performed. RESULTS: Immunohistochemistry identified CST in outer annulus, inner annulus, and nucleus tissue. Annulus cells exposed to TNF-α revealed significantly lower CST expression (p=.013). Exposure to CST significantly increased proliferation. Quantitative real-time polymerase chain reaction also confirmed expression of CST in vitro. CONCLUSIONS: Data provide the first evidence that CST is present in the human disc. Addition of CST significantly increased cell proliferation. Cortistatin expression was significantly downregulated by TNF-α exposure in vitro. Findings suggest possible in vivo reduction of the anti-inflammatory actions of CST because of elevated proinflammatory cytokines during degenerating disc.

The ferrous iron transporter FtrABCD is required for the virulence of Brucella abortus 2308 in mice.

Iron transport has been linked to the virulence of Brucella strains in both natural and experimental hosts. The genes designated BAB2_0837-0840 in the Brucella abortus 2308 genome sequence are predicted to encode a CupII-type ferrous iron transporter homologous to the FtrABCD transporter recently described in Bordetella. To study the role of the Brucella FtrABCD in iron transport, an isogenic ftrA mutant was constructed from B. abortus 2308. Compared with the parental strain, the B. abortus ftrA mutant displays a decreased capacity to use non-haem iron sources in vitro, a growth defect in a low iron medium that is enhanced at pH 6, and studies employing radiolabelled FeCl3 confirmed that FtrABCD transports ferrous iron. Transcription of the ftrA gene is induced in B. abortus 2308 in response to iron deprivation and exposure to acid pH, and similar to other Brucella iron acquisition genes that have been examined the iron-responsiveness of ftrA is dependent upon the iron response regulator Irr. The B. abortus ftrA mutant exhibits significant attenuation in both cultured murine macrophages and experimentally infected mice, supporting the proposition that ferrous iron is a critical iron source for these bacteria in the mammalian host.

The bhuQ gene encodes a heme oxygenase that contributes to the ability of Brucella abortus 2308 to use heme as an iron source and is regulated by Irr.

The Brucella BhuQ protein is a homolog of the Bradyrhizobium japonicum heme oxygenases HmuD and HmuQ. To determine if this protein plays a role in the ability of Brucella abortus 2308 to use heme as an iron source, an isogenic bhuQ mutant was constructed and its phenotype evaluated. Although the Brucella abortus bhuQ mutant DCO1 did not exhibit a defect in its capacity to use heme as an iron source or evidence of increased heme toxicity in vitro, this mutant produced increased levels of siderophore in response to iron deprivation compared to 2308. Introduction of a bhuQ mutation into the B. abortus dhbC mutant BHB2 (which cannot produce siderophores) resulted in a severe growth defect in the dhbC bhuQ double mutant JFO1 during cultivation under iron-restricted conditions, which could be rescued by the addition of FeCl(3), but not heme, to the growth medium. The bhuQ gene is cotranscribed with the gene encoding the iron-responsive regulator RirA, and both of these genes are repressed by the other major iron-responsive regulator in the alphaproteobacteria, Irr. The results of these studies suggest that B. abortus 2308 has at least one other heme oxygenase that works in concert with BhuQ to allow this strain to efficiently use heme as an iron source. The genetic organization of the rirA-bhuQ operon also provides the basis for the proposition that BhuQ may perform a previously unrecognized function by allowing the transcriptional regulator RirA to recognize heme as an iron source.

Mur regulates the gene encoding the manganese transporter MntH in Brucella abortus 2308.

MntH is the only high-affinity manganese transporter identified in Brucella. A previous study showed that MntH is required for the wild-type virulence of Brucella abortus 2308 in mice (Anderson ES, et al., Infect. Immun. 77:3466-3474, 2009) and indicated that the mntH gene is regulated in a manganese-responsive manner in this strain by a Mur homolog. In the study presented here, the transcriptional start site for mntH in B. abortus 2308 was determined by primer extension analysis. Specific interactions between Mur and the mntH promoter region were demonstrated in an electrophoretic mobility shift assay (EMSA), and a Mur binding site was identified in the -55 to -24 region of the mntH promoter by DNase I footprint analysis. The specificity of the interaction of Mur with the putative Mur box was further evaluated by EMSA employing oligonucleotides in which the consensus nucleotides in this region were substituted. These studies not only confirm a direct role for Mur in the Mn-responsive regulation of mntH expression in Brucella abortus 2308 but also identify the cis-acting elements upstream of mntH that are responsible for this regulation.

The manganese transporter MntH is a critical virulence determinant for Brucella abortus 2308 in experimentally infected mice.

The gene designated BAB1_1460 in the Brucella abortus 2308 genome sequence is predicted to encode the manganese transporter MntH. Phenotypic analysis of an isogenic mntH mutant indicates that MntH is the sole high-affinity manganese transporter in this bacterium but that MntH does not play a detectable role in the transport of Fe(2+), Zn(2+), Co(2+), or Ni(2+). Consistent with the apparent selectivity of the corresponding gene product, the expression of the mntH gene in B. abortus 2308 is repressed by Mn(2+), but not Fe(2+), and this Mn-responsive expression is mediated by a Mur-like repressor. The B. abortus mntH mutant MWV15 exhibits increased susceptibility to oxidative killing in vitro compared to strain 2308, and a comparative analysis of the superoxide dismutase activities present in these two strains indicates that the parental strain requires MntH in order to make wild-type levels of its manganese superoxide dismutase SodA. The B. abortus mntH mutant also exhibits extreme attenuation in both cultured murine macrophages and experimentally infected C57BL/6 mice. These experimental findings indicate that Mn(2+) transport mediated by MntH plays an important role in the physiology of B. abortus 2308, particularly during its intracellular survival and replication in the host.