NHERF2 Protein Mobility Rate Is Determined by a Unique C-terminal Domain That Is Also Necessary for Its Regulation of NHE3 Protein in OK Cells

Na⁺/H⁺ exchanger regulatory factor (NHERF) proteins are a family of PSD-95/Discs-large/ZO-1 (PDZ)-scaffolding proteins, three of which (NHERFs 1-3) are localized to the brush border in kidney and intestinal epithelial cells. All NHERF proteins are involved in anchoring membrane proteins that contain PDZ recognition motifs to form multiprotein signaling complexes. In contrast to their predicted immobility, NHERF1, NHERF2, and NHERF3 were all shown by fluorescence recovery after photobleaching/confocal microscopy to be surprisingly mobile in the microvilli of the renal proximal tubule OK cell line. Their diffusion coefficients, although different among the three, were all of the same magnitude as that of the transmembrane proteins, suggesting they are all anchored in the microvilli but to different extents. NHERF3 moves faster than NHERF1, and NHERF2 moves the slowest. Several chimeras and mutants of NHERF1 and NHERF2 were made to determine which part of NHERF2 confers the slower mobility rate. Surprisingly, the slower mobility rate of NHERF2 was determined by a unique C-terminal domain, which includes a nonconserved region along with the ezrin, radixin, moesin (ERM) binding domain. Also, this C-terminal domain of NHERF2 determined its greater detergent insolubility and was necessary for the formation of larger multiprotein NHERF2 complexes. In addition, this NHERF2 domain was functionally significant in NHE3 regulation, being necessary for stimulation by lysophosphatidic acid of activity and increased mobility of NHE3, as well as necessary for inhibition of NHE3 activity by calcium ionophore 4-Br-{"type":"entrez-nucleotide","attrs":{"text":"A23187","term_id":"833253","term_text":"A23187"}}A23187. Thus, multiple functions of NHERF2 require involvement of an additional domain in this protein.     

Pyridinylpyrimidines selectively inhibit human methionine aminopeptidase-1

Cellular protein synthesis is initiated with methionine in eukaryotes with few exceptions. Methionine aminopeptidases (MetAPs) which catalyze the process of N-terminal methionine excision are essential for all organisms. In mammals, type 2 MetAP (MetAP2) is known to be important for angiogenesis, while type 1 MetAP (MetAP1) has been shown to play a pivotal role in cell proliferation. Our previous high-throughput screening of a commercial compound library uncovered a novel class of inhibitors for both human MetAP1 (HsMetAP1) and human MetAP2 (HsMetAP2). This class of inhibitors contains a pyridinylpyrimidine core. To understand the structure–activity relationship (SAR) and to search for analogues of 2 with greater potency and higher HsMetAP1-selectivity, a total of 58 analogues were acquired through either commercial source or by in-house synthesis and their inhibitory activities against HsMetAP1 and HsMetAP2 were determined. Through this systematic medicinal chemistry analysis, we have identified (1) 5-chloro-6-methyl-2-pyridin-2-ylpyrimidine as the minimum element for the inhibition of HsMetAP1; (2) 5′-chloro as the favored substituent on the pyridine ring for the enhanced potency against HsMetAP1; and (3) long C4 side chains as the essentials for higher HsMetAP1-selectivity. At the end of our SAR campaign, 25b, 25c, 26d and 30a–30c are among the most selective and potent inhibitors of purified HsMetAP1 reported to date. In addition, we also performed crystallographic analysis of one representative inhibitor (26d) in complex with N-terminally truncated HsMetAP1.     

Sex differences in kidney gene expression during the life cycle of F344 rats

Background

The kidney functions in key physiological processes to filter blood and regulate blood pressure via key molecular transporters and ion channels. Sex-specific differences have been observed in renal disease incidence and progression, as well as acute kidney injury in response to certain drugs. Although advances have been made in characterizing the molecular components involved in various kidney functions, the molecular mechanisms responsible for sex differences are not well understood. We hypothesized that the basal expression levels of genes involved in various kidney functions throughout the life cycle will influence sex-specific susceptibilities to adverse renal events.

Methods

Whole genome microarray gene expression analysis was performed on kidney samples collected from untreated male and female Fischer 344 (F344) rats at eight age groups between 2 and 104 weeks of age.

Results

A combined filtering approach using statistical (ANOVA or pairwise t test, FDR 0.05) and fold-change criteria (>1.5 relative fold change) was used to identify 7,447 unique differentially expressed genes (DEGs). Principal component analysis (PCA) of the 7,447 DEGs revealed sex-related differences in mRNA expression at early (2 weeks), middle (8, 15, and 21 weeks), and late (104 weeks) ages in the rat life cycle. Functional analysis (Ingenuity Pathway Analysis) of these sex-different genes indicated over-representation of specific pathways and networks including renal tubule injury, drug metabolism, and immune cell and inflammatory responses. The mRNAs that code for the qualified urinary protein kidney biomarkers KIM-1, Clu, Tff3, and Lcn2 were also observed to show sex differences.

Conclusions

These data represent one of the most comprehensive in-life time course studies to be published, assessing sex differences in global gene expression in the F344 rat kidney. PCA and Venn analyses reveal specific periods of sexually dimorphic gene expression which are associated with functional categories (xenobiotic metabolism and immune cell and inflammatory responses) of key relevance to acute kidney injury and chronic kidney disease, which may underlie sex-specific susceptibility. Analysis of the basal gene expression patterns of renal genes throughout the life cycle of the rat will improve the use of current and future renal biomarkers and inform our assessments of kidney injury and disease.

     

Escherichia coli O104 in Feedlot Cattle Feces: Prevalence,Isolation and Characterization

Escherichia coli O104:H4, an hybrid pathotype of Shiga toxigenic and enteroaggregative E. coli, involved in a major foodborne outbreak in Germany in 2011, has not been detected in cattle feces. Serogroup O104 with H type other than H4 has been reported to cause human illnesses, but their prevalence and characteristics in cattle have not been reported. Our objectives were to determine the prevalence of E. coli O104 in feces of feedlot cattle, by culture and PCR detection methods, and characterize the isolated strains. Rectal fecal samples from a total of 757 cattle originating from 29 feedlots were collected at a Midwest commercial slaughter plant. Fecal samples, enriched in E. coli broth, were subjected to culture and PCR methods of detection. The culture method involved immunomagnetic separation with O104-specific beads and plating on a selective chromogenic medium, followed by serogroup confirmation of pooled colonies by PCR. If pooled colonies were positive for the wzx_O104 gene, then colonies were tested individually to identify wzx_O104-positive serogroup and associated genes of the hybrid strains. Extracted DNA from feces were also tested by a multiplex PCR to detect wzx_O104-positive serogroup and associated major genes of the O104 hybrid pathotype. Because wzx_O104 has been shown to be present in E. coli O8/O9/O9a, wzx_O104-positive isolates and extracted DNA from fecal samples were also tested by a PCR targeting wbdD_O8/O9/O9a, a gene specific for E. coli O8/O9/O9a serogroups. Model-adjusted prevalence estimates of E. coli O104 (positive for wzx_O104 and negative for wbdD_O8/O9/O9a) at the feedlot level were 5.7% and 21.2%, and at the sample level were 0.5% and 25.9% by culture and PCR, respectively. The McNemar’s test indicated that there was a significant difference (P < 0.01) between the proportions of samples that tested positive for wzx_O104 and samples that were positive for wzx_O104, but negative for wbdD_O8/O9/O9a by PCR and culture methods. A total of 143 isolates, positive for the wzx_O104, were obtained in pure culture from 146 positive fecal samples. Ninety-two of the 143 isolates (64.3%) also tested positive for the wbdD_O8/O9/O9a, indicating that only 51 (35.7%) isolates truly belonged to the O104 serogroup (positive for wzx_O104 and negative for wbdD_O8/O9/O9a). All 51 isolates tested negative for eae, and 16 tested positive for stx1 gene of the subtype 1c. Thirteen of the 16 stx1-positive O104 isolates were from one feedlot. The predominant serotype was O104:H7. Pulsed-field gel electrophoresis analysis indicated that stx1-positive O104:H7 isolates had 62.4% homology to the German outbreak strain and 67.9% to 77.5% homology to human diarrheagenic O104:H7 strains. The 13 isolates obtained from the same feedlot were of the same PFGE subtype with 100% Dice similarity. Although cattle do not harbor the O104:H4 pathotype, they do harbor and shed Shiga toxigenic O104 in the feces and the predominant serotype was O104:H7.     

Genomic annotation and validation of bacterial consortium NDMC-1 for enhanced degradation of sugarcane bagasse

This study aims at designing a consortium using rumen bacterial isolates for enhancing the hydrolysis of sugarcane bagasse (SB) for efficient biofuel formation. The microbial population was screened through biochemical and molecular tools along with enzymatic activity to obtain potential isolates for diverse cellulolytic and hemicellulolytic carbohydrate active enzyme (CAZyme). Five strains (Paenibacillus, Bacillus, Enterobacter, and Microbacterium) were selected for designing the consortium NDMC-1. The hydrolytic efficiency of NDMC-1 was determined based on cellulase production with simultaneous rise in monosaccharides, oligosaccharides, and soluble chemical oxygen demand (sCOD) concentration. Cellulolytic machinery of these isolates was further explored using genome sequencing. The isolates selected for consortia NDMC-1 interacted synergistically leading to enhanced cellulase production. Maximal endoglucanase (1.67 μmol ml−1 min−1), exoglucanase (0.69 μmol ml−1 min−1), and β-glucosidase (2.03 μmol ml−1 min−1) activity were achieved with SB as a sole carbon source after 48 h of incubation. Enhancement in SB hydrolysis employing NDMC-1 was evident by the increase in sCOD from 609 to 2589 mg/l and release of 1295 mg/l reducing sugar, comprising 59.8%, 8.23%, and 6.16% of glucose, cellobiose, and cellotriose, respectively, which resulted in 5.5-fold rise in biogas production. On genome annotation, total 472 contigs from glycoside hydrolase family: 84 from Microbacterium arborescens ND21, 72 from Enterobacter cloacae ND22, 61 from Bacillus subtilis ND23, 116 from Paenibacillus polymyxa ND24, and 140 from Paenibacillus polymyxa ND25 were identified. On further analysis, total 33 cellulases, 59 hemicellulases, and 48 esterases were annotated in the reported genomes. This work proposes the application of consortia-based bioprocessing systems over the conventionally favorable single organism approach for efficient hydrolysis of cellulosic substrates to fermentable sugars.     

DYRK1A regulates the recruitment of 53BP1 to the sites of DNA damage in part through interaction with RNF169

Human Dual-specificity tyrosine (Y) Regulated Kinase 1A (DYRK1A) is encoded by a dosage dependent gene whereby either trisomy or haploinsufficiency result in developmental abnormalities. However, the function and regulation of this important protein kinase are not fully understood. Here, we report proteomic analysis of DYRK1A in human cells that revealed a novel role of DYRK1A in DNA double-strand breaks (DSBs) repair, mediated in part by its interaction with the ubiquitin-binding protein RNF169 that accumulates at the DSB sites and promotes homologous recombination repair (HRR) by displacing 53BP1, a key mediator of non-homologous end joining (NHEJ). We found that overexpression of active, but not the kinase inactive DYRK1A in U-2 OS cells inhibits accumulation of 53BP1 at the DSB sites in the RNF169-dependent manner. DYRK1A phosphorylates RNF169 at two sites that influence its ability to displace 53BP1 from the DSBs. Although DYRK1A is not required for the recruitment of RNF169 to the DSB sites and 53BP1 displacement, inhibition of DYRK1A or mutation of the DYRK1A phosphorylation sites in RNF169 decreases its ability to block accumulation of 53BP1 at the DSB sites. Interestingly, CRISPR-Cas9 knockout of DYRK1A in human and mouse cells also diminished the 53BP1 DSB recruitment in a manner that did not require RNF169, suggesting that dosage of DYRK1A can influence the DNA repair processes through both RNF169-dependent and independent mechanisms. Human U-2 OS cells devoid of DYRK1A display an increased HRR efficiency and resistance to DNA damage, therefore our findings implicate DYRK1A in the DNA repair processes.     

Effects of an antiprogestin onapristone on the endometrium of bonnet monkeys: morphometric and ultrastructural studies

Our previous studies demonstrated the ability of low doses of antiprogestin ZK 98.299 (onapristone) to inhibit fertility in bonnet monkeys. In the present study cumulative effects of low doses of ZK 98.299 on the endometrial cytoarchitecture of bonnet monkeys were analyzed. Treatment with either the vehicle (n = 3) or onapristone at 2.5 mg (n = 4) or 5.0 mg (n = 3) was initiated on Day 5 of the first menstrual cycle and thereafter repeated every third day for four to seven consecutive cycles. The last treatment cycles were anovulatory in two animals treated with 2.5 mg and all animals treated with 5.0 mg. Endometrial biopsies were collected on Day 8 after the midcycle estradiol peak in ovulatory menstrual cycles and on Day 20 in anovulatory menstrual cycles during the last treatment cycle. Ultrathin sections of the fixed endometrium were stained with toluidine blue for morphometric analysis and uranyl acetate and lead citrate for ultrastructural analysis. The ZK 98.299-treated animals showed a dose-dependent endometrial atrophy as evident by a decrease in the height and diameter of the glands and early signs of compaction in the stroma. Ultrastructural analysis also revealed dose-dependent degenerative changes in the subcellular organelles such as the nucleus, mitochondria, endoplasmic reticulum, lysosomes, and Golgi apparatus. This suggests that long-term treatment with low doses of ZK 98.299 leads to the suppression of estrogen-dependent endometrial proliferation. However, this blockade operates independent of estradiol receptor (ER) and progesterone receptor (PR) concentrations as the expressions of these steroid receptors did not show any significant changes even after prolonged treatment. The study demonstrated an antiestrogenic effect of ZK 98.299 on endometrium after prolonged treatment in bonnet monkeys.