Paneth cell alpha-defensin synthesis and function.

Endogenous antimicrobial peptides (AMPs) mediate innate immunity in every species in which they have been investigated. Cathelicidins and defensins are the two major AMP families in mammals, and they are abundant components of phagocytic leukocytes and are released by epithelial cells at mucosal surfaces. In the small intestine, Paneth cells at the base of the crypts of Lieberkühn secrete alpha-defensins and additional AMPs at high levels in response to cholinergic stimulation and when exposed to bacterial antigens. Paneth cell alpha-defensins evolved to function in the extracellular environment with broad-spectrum antimicrobial activities, and they constitute the majority of bactericidal peptide activity secreted by Paneth cells. The release of Paneth cell products into the crypt lumen is inferred to protect mitotically active crypt cells from colonization by potential pathogens and confers protection from enteric infection, as is evident from the immunity of mice expressing a human Paneth cell alpha-defensin transgene to oral infection by Salmonella enterica serovar Typhimurium. alpha-Defensins in Paneth cell secretions also may interact with bacteria in the intestinal lumen above the crypt-villus boundary and influence the composition of the enteric microbial flora. Mutations that cause defects in the activation, secretion, dissolution, and bactericidal effects of Paneth cell AMPs may alter crypt innate immunity and contribute to immunopathology.

Quantification of toxic Microcystis spp. during the 2003 and 2004 blooms in western Lake Erie using quantitative real-time PCR.

In August of 2003 and August of 2004, blooms of potentially toxic cyanobacteria Microcystis spp. persisted in western Lake Erie. Samples collected from the bloom were analyzed for the cyanobacterial toxin microcystin and the presence of Microcystis spp. cells. Estimates of microcystin toxicity exceeding 1 microg L(-1) (microcystin-LR activity equivalents), the safety limit set by the World Health Organization, were found from the samples in both 2003 and 2004. The presence of Microcystis spp. in water samples was confirmed through standard polymerase chain reaction (PCR) using a combination of four primer sets. Quantification of Microcystis was accomplished by a real-time PCR assay utilizing specific primer-Taq-man probe sets targeted on a conserved, Microcystis-specific 16S rDNA fragment and a microcystin toxin synthetase gene mcyD. This approach allowed us to specifically study the distribution and abundance of toxic Microcystis in the lake in contrast to previous studies that have assessed Microcystis populations with less refined methods. On the basis of quantification by quantitative real-time PCR analysis, the total abundance of Microcystis cells in the bloom area varied from 4 x 10(8) to 2 x 10(3) cells L(-1). The results of this study provide novel insight regarding the distribution and abundance of Microcystis spp. in the western basin of Lake Erie, a region plagued in recent years by large-scale (>20 km2) blooms. Our results suggest that the Maumee River and Bay may serve as a source for Microcystis to western and central Lake Erie.

Mucosal T cells regulate Paneth and intermediate cell numbers in the small intestine of T. spiralis-infected mice.

Secretions of Paneth, intermediate and goblet cells have been implicated in innate intestinal host defense. We have investigated the role of T cells in effecting alterations in small intestinal epithelial cell populations induced by infection with the nematode Trichinella spiralis. Small intestinal tissue sections from euthymic and athymic (nude) mice, and mice with combined deficiency in T-cell receptor beta and delta genes [TCR(beta/delta)-/-] infected orally with T. spiralis larvae, were examined by electron microscopy and after histochemical and lineage-specific immunohistochemical staining. Compared with uninfected controls, Paneth and intermediate cell numbers increased significantly in infected euthymic and nude mice but not infected TCR(beta/delta)-/- mice. Transfer of mesenteric lymph node cells before infection led to an increase in Paneth and intermediate cells in TCR(beta/delta)-/- mice. In infected euthymic mice, Paneth cells and intermediate cells expressed cryptdins (alpha-defensins) but not intestinal trefoil factor (ITF), and goblet cells expressed ITF but not cryptdins. In conclusion, a unique, likely thymic-independent population of mucosal T cells modulates innate small intestinal host defense in mice by increasing the number of Paneth and intermediate cells in response to T. spiralis infection.

Characterization of luminal paneth cell alpha-defensins in mouse small intestine. Attenuated antimicrobial activities of peptides with truncated amino termini.

Paneth cells at the base of small intestinal crypts secrete apical granules that contain antimicrobial peptides including alpha-defensins, termed cryptdins. Using an antibody specific for mouse cryptdin-1, -2, -3, and -6, immunogold-localization studies demonstrated that cryptdins are constituents of mouse Paneth cell secretory granules. Several cryptdin peptides have been purified from rinses of adult mouse small intestine by gel filtration and reverse-phase high performance liquid chromatography. Their primary structures were determined by peptide sequencing, and their antimicrobial activities were compared with those of the corresponding tissue forms. The isolated luminal cryptdins included peptides identical to the tissue forms of cryptdin-2, -4, and -6 as well as variants of cryptdin-1, -4, and -6 that have N termini truncated by one or two residues. In assays of antimicrobial activity against Staphylococcus aureus, Escherichia coli, and the defensin-sensitive Salmonella typhimurium phoP(-) mutant, full-length cryptdins had the same in vitro antibacterial activities whether isolated from tissue or from the lumen. In contrast, the N-terminal-truncated (des-Leu), (des-Leu-Arg)-cryptdin-6, and (des-Gly)-cryptdin-4 peptides were markedly less active. The microbicidal activities of recombinant cryptdin-4 and (des-Gly)-cryptdin-4 peptides against E. coli, and S. typhimurium showed that the N-terminal Gly residue or the length of the cryptdin-4 N terminus are determinants of microbicidal activity. Innate immunity in the crypt lumen may be modulated by aminopeptidase modification of alpha-defensins after peptide secretion.

Probing the structure of photosystem II with amines and phenylhydrazine.

Photosynthetic oxygen evolution is catalyzed at the manganese-containing active site of photosystem II (PSII). Amines are analogs of substrate water and inhibitors of oxygen evolution. Recently, the covalent incorporation of (14)C from [(14)C]methylamine and benzylamine into PSII subunits has been demonstrated (Ouellette, A. J. A., Anderson, L. B., and Barry, B. A. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 2204-2209). To obtain more information concerning these labeling reactions, t-[(14)C]butylamine and phenylhydrazine were employed as probes. Neither compound can be oxidized by a transamination or addition/elimination mechanism, but both can react with activated carbonyl groups, produced as a result of posttranslational modification of amino acid residues, to give amine-derived adducts. (14)C incorporation into the PSII subunits D2/D1 and CP47 was obtained upon treatment of PSII with either t-[(14)C]butylamine or [(14)C]phenylhydrazine. For t-butylamine and methylamine, the amount of labeling increased when PSII was treated with denaturing agents. Labeling of CP47, D2, and D1 with methylamine and phenylhydrazine approached a one-to-one stoichiometry, assuming that D2 and D1 each have one binding site. Evidence was obtained suggesting that reductive stabilization and/or access are modulated by PSII light reactions. These results support the proposal that PSII subunits D2, D1, and CP47 contain quinocofactors and that access to these sites is sterically limited.

Secretion of microbicidal alpha-defensins by intestinal Paneth cells in response to bacteria.

Paneth cells in mouse small intestinal crypts secrete granules rich in microbicidal peptides when exposed to bacteria or bacterial antigens. The dose-dependent secretion occurs within minutes and alpha-defensins, or cryptdins, account for 70% of the released bactericidal peptide activity. Gram-negative bacteria, Gram-positive bacteria, lipopolysaccharide, lipoteichoic acid, lipid A and muramyl dipeptide elicit cryptdin secretion. Live fungi and protozoa, however, do not stimulate degranulation. Thus intestinal Paneth cells contribute to innate immunity by sensing bacteria and bacterial antigens, and discharge microbicidal peptides at effective concentrations accordingly.

Peptide localization and gene structure of cryptdin 4, a differentially expressed mouse paneth cell alpha-defensin.

Paneth cells in crypts of the small intestine express antimicrobial peptides, including alpha-defensins, termed cryptdins in mice. Of the known Paneth cell alpha-defensins, the cryptdin 4 gene is unique, because it is inactive in the duodenum and expressed at maximal levels in the distal small bowel (D. Darmoul and A. J. Ouellette, Am. J. Physiol. 271:G68-G74, 1996). With a cryptdin 4-specific antibody, immunohistochemical staining of ileal Paneth cells was strong and specific for cytoplasmic granules, demonstrating that this microbicidal peptide is a secretory product of Paneth cells in the distal small intestine. Consistent with the pattern of cryptdin 4 mRNA distribution along the length of the gut, the cryptdin 4 peptide was not detected in duodenum. Structurally, the cryptdin 4 gene resembles other Paneth cell alpha-defensin genes. Its two exons, transcriptional start site, intron, splice sites, and 3' flanking sequences are characteristic of the highly conserved mouse alpha-defensin genes. However, in the region upstream of the transcriptional initiation site, the cryptdin 4 gene contains a repeated 130-bp element that is unique to this alpha-defensin gene. Every independent cryptdin 4 genomic clone examined carries the repeated element, which contains putative recognition sequences for TF-IID-EIIA, cMyc-RS-1, and IgHC.2/CuE1.1; the repeat proximal to the start of transcription replaces DNA at the corresponding position in other mouse alpha-defensin genes. We speculate that this unique duplicated element may have a cis-acting regulatory role in the positional specificity of cryptdin 4 gene expression.

A cyclic antimicrobial peptide produced in primate leukocytes by the ligation of two truncated alpha-defensins.

Analysis of rhesus macaque leukocytes disclosed the presence of an 18-residue macrocyclic, tridisulfide antibiotic peptide in granules of neutrophils and monocytes. The peptide, termed rhesus theta defensin-1 (RTD-1), is microbicidal for bacteria and fungi at low micromolar concentrations. Antibacterial activity of the cyclic peptide was threefold greater than that of an open-chain analog, and the cyclic conformation was required for antimicrobial activity in the presence of 150 millimolar sodium chloride. Biosynthesis of RTD-1 involves the head-to-tail ligation of two alpha-defensin-related nonapeptides, requiring the formation of two new peptide bonds. Thus, host defense cells possess mechanisms for synthesis and granular packaging of macrocyclic antibiotic peptides that are components of the phagocyte antimicrobial armamentarium.

Regulation of intestinal alpha-defensin activation by the metalloproteinase matrilysin in innate host defense.

Precursors of alpha-defensin peptides require activation for bactericidal activity. In mouse small intestine, matrilysin colocalized with alpha-defensins (cryptdins) in Paneth cell granules, and in vitro it cleaved the pro segment from cryptdin precursors. Matrilysin-deficient (MAT-/-) mice lacked mature cryptdins and accumulated precursor molecules. Intestinal peptide preparations from MAT-/- mice had decreased antimicrobial activity. Orally administered bacteria survived in greater numbers and were more virulent in MAT-/- mice than in MAT+/+ mice. Thus, matrilysin functions in intestinal mucosal defense by regulating the activity of defensins, which may be a common role for this metalloproteinase in its numerous epithelial sites of expression.

IV. Paneth cell antimicrobial peptides and the biology of the mucosal barrier.

The hypothesis that epithelial cells release preformed antibiotic peptides as components of mucosal innate immunity has gained experimental support in recent years. In the mammalian small intestine, Paneth cells secrete granules that are rich in alpha-defensins and additional antimicrobial peptides into the lumen of the crypt. The alpha-defensins are homologues of peptides that function as mediators of nonoxidative microbial cell killing in phagocytic leukocytes, and they are potent microbicidal agents in in vitro assays. Because certain mouse alpha-defensins stimulate cultured epithelial cells to secrete chloride ion, those peptides appear to be capable of interacting directly with the apical membranes of neighboring cells and perhaps influencing crypt physiology. In instances of crypt disruption or induced Paneth cell deficiency, crypt intermediate cells appear to compensate by accumulating and secreting Paneth cell antimicrobial peptides. Challenges for the future will be to understand the mechanisms of this epithelial plasticity and to show that Paneth cells contribute directly to innate immunity in the crypt microenvironment.

Amine binding and oxidation at the catalytic site for photosynthetic water oxidation.

Photosynthetic water oxidation occurs at the Mn-containing catalytic site of photosystem II (PSII). By the use of 14C-labeled amines and SDS-denaturing PAGE, covalent adducts derived from primary amines and the PSII subunits, CP47, D2/D1, and the Mn-stabilizing protein, can be observed. When PSII contains the 18- and 24-kDa extrinsic proteins, which restrict access to the active site, no 14C labeling is obtained. NaCl, but not Na2SO4, competes with 14C labeling in Mn-containing PSII preparations, and the concentration dependence of this competition parallels the activation of oxygen evolution. Formation of 14C-labeled adducts is observed in the presence or in the absence of a functional manganese cluster. However, no significant Cl- effect on 14C labeling is observed in the absence of the Mn cluster. Isolation and quantitation of the 14C-labeled aldehyde product, produced from [14C]benzylamine, gives yields of 1. 8 +/- 0.3 mol/mol PSII and 2.9 +/- 0.2 mol/mol in Mn-containing and Mn-depleted PSII, respectively. The corresponding specific activities are 0.40 +/- 0.07 micromol(micromol PSII-hr)-1 and 0.64 +/- 0.04 micromol(micromol PSII-hr)-1. Cl- suppresses the production of [14C]benzaldehyde in Mn-containing PSII, but does not suppress the production in Mn-depleted preparations. Control experiments show that these oxidation reactions do not involve the redox-active tyrosines, D and Z. Our results suggest the presence of one or more activated carbonyl groups in protein subunits that form the active site of PSII.

Paneth cells and innate immunity in the crypt microenvironment.

Paneth cells release granules into the lumen of the crypts of Lieberkuhn in the small intestine where their component proteins participate in mucosal immunity. The granules contain a number of proteins associated with roles in host defense, including lysozyme, secretory phospholipase A2, and alpha-defensins, termed cryptdins. Mouse cryptdins 1-6 and recombinant human Paneth cell alpha-defensin HD-5 are potent antimicrobial agents against certain microorganisms. As defensins, they kill microbes by disruption of the target cell membrane. The peptides are coded by individual, two-exon genes that map to homologous regions of chromosome 8 in mice and humans, and the differential expression of certain mouse cryptdin genes provides markers for studies of crypt ontogeny and epithelial cell differentiation and lineage determination. Neutrophil alpha-defensin peptides exhibit numerous biological activities in addition to antimicrobial function including regulation of cell volume, chemotaxis, mitogenicity, and inhibition of natural killer cell activity. When administered apically, mouse cryptdins 2 and 3 can reversibly stimulate human T-84 intestinal epithelial cells to secrete chloride ion, suggesting that alpha-defensins from Paneth cells also may be multifunctional. Thus, cryptdins and varied Paneth cell secretory products seem to contribute both to innate immunity of the crypt lumen and to defining the apical environment of neighboring cells.

Induction of epithelial chloride secretion by channel-forming cryptdins 2 and 3.

Salt and water secretion from intestinal epithelia requires enhancement of anion permeability across the apical membrane of Cl- secreting cells lining the crypt, the secretory gland of the intestine. Paneth cells located at the base of the small intestinal crypt release enteric defensins (cryptdins) apically into the lumen. Because cryptdins are homologs of molecules known to form anion conductive pores in phospholipid bilayers, we tested whether these endogenous antimicrobial peptides could act as soluble inducers of channel-like activity when applied to apical membranes of intestinal Cl- secreting epithelial cells in culture. Of the six peptides tested, cryptdins 2 and 3 stimulated Cl- secretion from polarized monolayers of human intestinal T84 cells. The response was reversible and dose dependent. In contrast, cryptdins 1, 4, 5, and 6 lacked this activity, demonstrating that Paneth cell defensins with very similar primary structures may exhibit a high degree of specificity in their capacity to elicit Cl- secretion. The secretory response was not inhibited by pretreatment with 8-phenyltheophyline (1 microM), or dependent on a concomitant rise in intracellular cAMP or cGMP, indicating that the apically located adenosine and guanylin receptors were not involved. On the other hand, cryptdin 3 elicited a secretory response that correlated with the establishment of an apically located anion conductive channel permeable to carboxyfluorescein. Thus cryptdins 2 and 3 can selectively permeabilize the apical cell membrane of epithelial cells in culture to elicit a physiologic Cl- secretory response. These data define the capability of cryptdins 2 and 3 to function as novel intestinal secretagogues, and suggest a previously undescribed mechanism of paracrine signaling that in vivo may involve the reversible formation of ion conductive channels by peptides released into the crypt microenvironment.

Cryptdin gene expression in developing mouse small intestine.

In rodents, the four intestinal epithelial cell lineages differentiate and become morphologically distinct during the first 2-3 postnatal wk. In studies reported here, reverse transcriptase-polymerase chain reaction (RT-PCR)-based assays detected Paneth cell defensin mRNAs in intestinal RNA from 1-day-old (P1) mice before crypt formation and maturation of the epithelium. Analysis of these defensin-coding RT-PCR products from P1 mice showed that 69% of clones sequenced coded for cryptdin-6, suggesting that it is the most abundant enteric defensin mRNA in the newborn. Paneth cell mRNAs, including cryptdins-4 and -5, lysozyme, matrilysin, and defensin-related sequences, also were detected in RNA from P1 mouse intestine. Unlike adult mice, where only Paneth cells are immunopositive for cryptdin, cryptdin-containing cells were distributed throughout the newborn intestinal epithelium and not in association with rudimentary crypts. Cryptdin immunoreactivity in the P1 mouse intestine was specific for intracellular granule contents, and immunofluorescent detection of cryptdins on mucosal surfaces suggested that the peptides are released into the intestinal lumen in P1 mice Defensin secretion may contribute to innate immunity of the neonatal intestine before the presence of distinguishable Paneth cells.

Paneth cell defensins: endogenous peptide components of intestinal host defense.

Paneth cells are epithelial granulocytes at the base of the crypts of Lieberkühn in the small intestine of many mammalian species. These secretory cells contribute to mucosal barrier function by the apical release of granules containing a variety of antimicrobial products, including peptides termed cryptdins, for crypt defensins. In mice, six Paneth cell defensins have been characterized at the peptide level that have potent antimicrobial activities equivalent to or greater than that of rabbit neutrophil defensin NP-1. Cryptdin peptides that differ only by single amino acid substitutions have been shown to exhibit a high degree of specificity against certain target microorganisms. Cryptdins are coded by separate, two-exon genes that are located on chromosome 8 in both mice and humans. Human Paneth cells contain high levels of two different defensin mRNAs, but in mice at least 19 cryptdin isoforms are predicted from cDNA sequencing data. The mouse cryptdin-4 gene is expressed with positional specificity along the longitudinal intestinal axis, and cryptdin genes are active in the intestinal epithelium prior to Paneth cell differentiation. Accordingly, Paneth cell defensins are early markers of crypt ontogeny and are therefore useful in studies of lineage determination in the intestinal epithelium. Because cryptdins mediate innate immunity in the hostile environment of the intestinal lumen, it should be of interest to define biochemical and biophysical attributes that adapt these peptides to barrier function of mucosal surfaces.

Positional specificity of defensin gene expression reveals Paneth cell heterogeneity in mouse small intestine.

Cryptdins are antimicrobial peptides of the defensin family that are expressed specifically by Paneth cells in small intestinal crypts (M.E. Selsted, S.I. Miller, A.H. Henschen, and A.J. Ouellette. J. Cell Biol. 118: 929-936, 1992), and at least 17 cryptdin isoforms have been reported in mouse small intestine (A.J. Ouellette, M.M. Hsieh, M.T. Nosek, D.F. Cano-Gauci, K.M. Huttner, R.N. Buick, and M.E. Selsted. Infect. Immun. 62: 5040-5047, 1994). Analysis of cryptdin gene expression in adult mouse small bowel revealed that the cryptdin-4 isoform is differentially expressed along the proximal-to-distal intestinal axis. By peptide-specific reverse transcriptase-polymerase chain reaction-based assays, cryptdin-4 mRNA was found to be absent from the proximal small bowel, increasing to maximal levels in the ileum. In contrast, intestinal content of cryptdin-1 and -5 mRNAs was equivalent in duodenum, jejunum, and ileum, and Northern blot hybridization experiments were consistent with both sets of data. Similarly, individual crypts isolated from duodenum contain cryptdin-1 mRNA but not cryptdin-4 mRNA. Taken together, the results show that Paneth cells are heterogeneous, depending on their position along the longitudinal axis of the small bowel. The positional specificity of defensin gene expression suggests that cryptdins may be useful markers for investigating the establishment and maintenance of this epithelial lineage in the mouse small intestine.

Rat neutrophil defensins. Precursor structures and expression during neutrophilic myelopoiesis.

Defensins constitute a family of 3- to 4-kDa antimicrobial peptides that are stored in the cytoplasmic granules of neutrophils, some macrophages, and intestinal Paneth cells. We have assessed defensin gene expression during myeloid differentiation by first characterizing cDNAs for each of the four known rat neutrophil defensins (RatNP 1-4). The cDNA sequences revealed that the peptides are synthesized as 87-94 amino acid precursors, each containing signal, pro-, and mature peptide segments. RatNP-3 and -4 mRNAs, but not those for RatNP-1 and -2 or other myeloid defensins, contained unique polypurine tracts located close to the termination codon in the 3' untranslated region. By using cDNA probes and/or riboprobes, we evaluated defensin transcript levels in a variety of tissues and in the full spectrum of neutrophil precursors. By in situ hybridization, defensin mRNAs were localized to neutrophil precursors in the bone marrow, with the highest mRNA levels occurring in promyelocytes and somewhat lower signals occurring in myeloblasts and myelocytes. Defensin mRNAs were not detectable in bands or mature neutrophils, nor at significant levels in tissues other than bone marrow. The accumulation of defensin protein in bone marrow cells was assessed by immunohistochemical staining with anti-RatNP-1 Ab. RatNP 1-4 mRNAs and protein levels were then correlated for each stage of neutrophilic differentiation to reveal the maturational profile of myeloid defensin gene expression in the rat.

Defensins in granules of phagocytic and non-phagocytic cells.

Antimicrobial proteins stored in lysosome-like granules of neutrophils and macrophages probably play an important role in killing phagocytosed microbes after delivery to the phagolysosome. Among the granules' antimicrobial armamentarium are defensins, peptides that kill a broad spectrum of microorganisms in vitro. Antimicrobial defensins were recently also isolated from non-phagocytic granulocytes of the mouse small intestinal epithelium, from where they are secreted into the lumen to function extracellularly. Clarification of the antimicrobial mechanisms of defensins in intracellular and extracellular environments will provide a key to understanding peptide-mediated host defence.