Two Different Copy Number Variations of the CLCN2 Gene in Chinese Cattle and Their Association with Growth Traits

Copy number variation (CNV) can affect gene function and even individual phenotypic traits by changing the transcription and translation level of related genes, and it also plays an important role in species evolution. Chloride voltage-gated channel 2 (CLCN2) encodes a voltage-gated chloride channel (CLC-2), which has a wide organ distribution and is ubiquitously expressed. Based on previous studies, we hypothesize that CLCN2 could be a candidate gene involved in cell volume regulation, transepithelial transport and cell proliferation. This study aimed to explore CNVs in the CLCN2 gene and investigate its association with growth traits in four Chinese cattle breeds (Yunling cattle, Xianan cattle, Qinchuan cattle and Pinan cattle). We identified there are two copy number variation regions (CNV1: 3600 bp, including exon 2–11; CNV2: 4800 bp, including exon 21–22) of the CLCN2 gene. The statistical analysis showed that the CNV1 mutation in the YL cattle population was significantly associated with cannon circumference (p < 0.01). The CNV2 mutation in the XN cattle population had a significant effect on body slanting length, chest girth and body weight (p < 0.05). In the YL cattle, the association analysis of CLCN2 gene CNV1 and CNV2 combination with cannon circumference was significant (p < 0.01). Our results provide evidence that CNV1 and CNV2 in CLCN2 are associated with growth traits in two different cattle populations and could be used as candidate markers for cattle molecular breeding.

Protease Domain Exosites Regulate Plasma Recovery and Extravascular Distribution of Factor IX(a) Variants in Hemophilic Mice

Introduction: Among the coagulation protease, factor IX (FIX) is unique in that a substantial pool of extravascular factor exists that contributes to in vivo hemostasis. Extravascular distribution of FIX contributes to poor plasma recovery of infused FIX in hemophilia B (HB). The effect of mutations in the heparin (K126A/K132A) and antithrombin (R150A) binding exosites of FIX and FIXa on the distribution of these variants between the plasma and extravascular binding sites was examined in HB and hemophilia A (HA) mice, respectively. Methods: Recombinant human FIX wild type (18 U/kg) or equimolar FIX K126A/K132A was administered to HB mice (n=8) via tail vein injection with sacrifice 5 min post-injection following retro-orbital blood collection. Equimolar doses of human FIXa wild type (WT), K126A/K132A and R150A were similarly injected into HA mice (n=4-8), with blood collection and sacrifice 5 min post-injection. Plasma was isolated by centrifugation, organs (liver, spleen, kidneys, heart, lung, and brain) harvested, rinsed with PBS, weighed, with a portion made into tissue lysates and remainder frozen. FIX(a) content of tissue lysates was determined by a species-specific human FIX(a) ELISA with variant-specific standard curves. Tissue concentration was determined by total FIX(a) present in lysate (ng) divided by respective tissue weight (mg). Organ distribution was determined by extrapolating FIX(a) tissue concentration to total organ weight. The FIX(a) present in a specific organ was divided by the administered FIX(a) dose to determine the % organ distribution. Results: PK studies in HB mice demonstrated that FIX WT and R150A demonstrated a similar pattern and time course of elimination. In contrast, FIX K126A/K132A demonstrated ~2.4 fold higher plasma recovery relative to FIX WT. Based on plasma concentrations at 5 min post-injection (plasma volume 40 ml/kg), ~12.9% of FIX WT and 30.5% of FIX K126A/K132A was localized to the plasma compartment. Tissue lysates from the liver, spleen, kidney and brain demonstrated that liver had the highest FIX content by far, with ~41% of the FIX WT dose at 5 min post-injection. Other tissues demonstrated markedly less FIX WT content, including kidney (1%), spleen (0.1%) and brain (undetectable). FIX tissue concentration was significantly higher in the liver (0.69 ng/mg tissue) compared to other tissues, followed by kidney (0.07 ng/mg), spleen (0.02 ng/mg) and brain (undetectable). Comparison of FIX K126A/K132A tissue content to WT demonstrated reduced liver localization (25% dose) with concomitant reduction in tissue concentration (0.45 ng/mg). In contrast, FIX K126A/K132A increased localization to the kidney (1.7%) and spleen (0.37%) relative to WT. In protease PK studies, FIXa K126A/K132A and R150A both enhanced plasma recovery (2.2-2.5 fold) in HA mice compared to FIXa WT. Based on plasma concentrations at 5 min post-injection, ~16.1% of FIXa WT and 41.1% of FIXa K126A/K132A dose localized in the plasma compartment. Similar to zymogen, tissue lysates demonstrated that liver had the highest FIXa WT content (28%). Other tissues contained markedly less FIXa, including kidney (2.4%), spleen (0.2%), heart (0.5%) and brain (undetectable). Similarly, FIXa tissue concentration was 4-fold higher in the liver (0.47 ng/mg) compared to other tissues, followed by kidney (0.12 ng/mg), spleen and heart (0.06 ng/mg) and brain (undetectable). Localization of FIXa K126A/K132A to the liver was reduced by nearly half compared to FIXa WT (16%) with reduction in liver tissue concentration (0.29 ng/mg). FIXa K126A/K132A had increased localization to the kidney (3.3%) relative to WT. In contrast, FIXa R150A (not shown) had similar liver distribution (31.9% dose) and tissue concentration (0.53 ng/mg) to FIXa WT, despite increased localization to the plasma (36.2%). Conclusions: Liver is the predominant organ for extravascular FIX binding and the heparin binding exosite contributes to this localization, similar to the collagen IV binding site in the Gla domain. Heparan sulfate and collagen IV co-localize in the basement membrane suggesting synergistic roles. FIXa also localizes to extravascular sites via the heparin-binding exosite, although that binding may be modestly limited by endogenous FIX in the HA mouse. Disruption of the antithrombin binding exosite re-distributes FIXa to the plasma compartment by an independent mechanism, as liver content is unchanged. Disclosures Sheehan: Bayer: Consultancy, Research Funding; Roche: Consultancy, Research Funding; BioMarin: Consultancy, Research Funding.

Epidemiological, Morphometric, and Molecular Investigation of Cystic Echinococcosis in Camel and Cattle From Upper Egypt: Current Status and Zoonotic Implications

Cystic echinococcosis has been considered one of the major parasitic zoonoses which is associated with severe economic losses. The present study was undertaken to investigate the occurrence, organ distribution, cyst fertility, and viability of cystic echinococcosis in slaughtered camels and cattle from various abattoirs in Assiut Governorate, Egypt. The work also involved morphological, morphometric, and molecular identification of the parasite. The occurrence of hydatid cysts was investigated in total number of 100 lungs of camels and 574 liver and lungs of cattle admitted to three slaughterhouses at Assiut Governorate, Egypt. Moreover, several individual variable factors, including organ involvement, age, sex, and hydatid cyst characteristics, were studied to identify their possible association with the occurrence of the disease. Genomic DNA was extracted from the hydatid cysts, followed by molecular identification of the parasite through amplification of ribosomal DNA internal transcribed spacer (ITS) regions. Hydatid cysts were found in 6 camels (6%) out of 100 inspected camels, while 5 hydatid cysts (0.87%) were detected in a total number of 574 cattle examined. The parasite was detected exclusively in lungs of camels, while lungs were the main organ infected by the parasite in cattle and one hydatid cyst was found in the liver (0.17%). In camel, 66.7, 16.65, and 16.65%of detected cysts were fertile, sterile, and calcified, respectively, while in cattle, these percentages were 60, 20, and 20%, respectively. None of the studied variable factors were significantly associated with the occurrence of the disease in camels, with the exception that all cysts were found in the lung. Conversely, we found a significant association (P &lt; 0.05) between the age and sex of the slaughtered cattle and the occurrence of hydatid cysts. In this respect, the rate of infection was higher in female cattle and those cattle more than 5 years (P &lt; 0.05). The morphological, morphometric, and molecular studies confirmed the presence of the parasite. Taken together, our results concluded that camels and cattle play a potential role in maintaining the transmission cycle of this zoonotic parasite.

Improved Radiolytic Stability of a 68Ga-labelled Collagelin Analogue for the Imaging of Fibrosis

There is an unmet medical need for non-invasive, sensitive, and quantitative methods for the assessment of fibrosis. Herein, an improved collagelin analogue labelled with gallium-68 for use with positron emission tomography (PET) is presented. A cyclic peptide, c[CPGRVNleHGLHLGDDEGPC], was synthesized by solid-phase peptide synthesis, conjugated to 2-(4,7-bis(2-(tert-butoxy)-2-oxoethyl)-1,4,7-triazonan-1-yl)acetic acid, and labelled with gallium-68. High performance liquid chromatography (HPLC) was used for the quality and stability assessment of the collagelin analogue. Non-specific organ distribution, blood clearance, and excretion rates were investigated in healthy mice and rats using ex vivo organ distribution analysis and dynamic in vivo PET/CT. Mice with carbon tetrachloride (CCl4) induced liver fibrosis were used for the investigation of specific binding via in vitro frozen section autoradiography, ex vivo organ distribution, and in vivo PET/CT. A non-decay corrected radiochemical yield (48 ± 6%) of [68Ga]Ga-NOTA-PEG2-c[CPGRVNleHGLHLGDDEGPC] ([68Ga]Ga-NO2A-[Nle13]-Col) with a radiochemical purity of 98 ± 2% was achieved without radical scavengers. The 68Ga-labelling was regioselective and stable at ambient temperature for at least 3 h. The autoradiography of the cryosections of fibrotic mouse liver tissue demonstrated a distinct heterogeneous radioactivity uptake that correlated with the fibrosis scores estimated after Sirius Red staining. The blood clearance and tissue washout from the [68Ga]Ga-NO2A-[Nle13]-Col was fast in both normal and diseased mice. Dosimetry investigation in rats indicated the possibility for 4–5 PET/CT examinations per year. Radiolytic stability of the collagelin analogue was achieved by the substitution of methionine with norleucine amino acid residue without a deterioration of its binding capability. [68Ga]Ga-NO2A-[Nle13]-Col demonstrated a safe dosimetry profile suitable for repeated scanning.

A Semi Rigid Novel Hydroxamate AMPED-Based Ligand for 89Zr PET Imaging

In this work, we designed, developed, characterized, and investigated a new chelator and its bifunctional derivative for 89Zr labeling and PET-imaging. In a preliminary study, we synthesized two hexadentate chelators named AAZTHAS and AAZTHAG, based on the seven-membered heterocycle AMPED (6-amino-6-methylperhydro-1,4-diazepine) with the aim to increase the rigidity of the 89Zr complex by using N-methyl-N-(hydroxy)succinamide or N-methyl-N-(hydroxy)glutaramide pendant arms attached to the cyclic structure. N-methylhydroxamate groups are the donor groups chosen to efficiently coordinate 89Zr. After in vitro stability tests, we selected the chelator with longer arms, AAZTHAG, as the best complexing agent for 89Zr presenting a stability of 86.4 ± 5.5% in human serum (HS) for at least 72 h. Small animal PET/CT static scans acquired at different time points (up to 24 h) and ex vivo organ distribution studies were then carried out in healthy nude mice (n = 3) to investigate the stability and biodistribution in vivo of this new 89Zr-based complex. High stability in vivo, with low accumulation of free 89Zr in bones and kidneys, was measured. Furthermore, an activated ester functionalized version of AAZTHAG was synthesized to allow the conjugation with biomolecules such as antibodies. The bifunctional chelator was then conjugated to the human anti-HER2 monoclonal antibody Trastuzumab (Tz) as a proof of principle test of conjugation to biologically active molecules. The final 89Zr labeled compound was characterized via radio-HPLC and SDS-PAGE followed by autoradiography, and its stability in different solutions was assessed for at least 4 days.

A Novel UPLC-MS/MS Method Identifies Organ-Specific Dipeptide Profiles

Background: Amino acids have a central role in cell metabolism, and intracellular changes contribute to the pathogenesis of various diseases, while the role and specific organ distribution of dipeptides is largely unknown. Method: We established a sensitive, rapid and reliable UPLC-MS/MS method for quantification of 36 dipeptides. Dipeptide patterns were analyzed in brown and white adipose tissues, brain, eye, heart, kidney, liver, lung, muscle, sciatic nerve, pancreas, spleen and thymus, serum and urine of C57BL/6N wildtype mice and related to the corresponding amino acid profiles. Results: A total of 30 out of the 36 investigated dipeptides were detected with organ-specific distribution patterns. Carnosine and anserine were most abundant in all organs, with the highest concentrations in muscles. In liver, Asp-Gln and Ala-Gln concentrations were high, in the spleen and thymus, Glu-Ser and Gly-Asp. In serum, dipeptide concentrations were several magnitudes lower than in organ tissues. In all organs, dipeptides with C-terminal proline (Gly-Pro and Leu-Pro) were present at higher concentrations than dipeptides with N-terminal proline (Pro-Gly and Pro-Leu). Organ-specific amino acid profiles were related to the dipeptide profile with several amino acid concentrations being related to the isomeric form of the dipeptides. Aspartate, histidine, proline and serine tissue concentrations correlated with dipeptide concentrations, when the amino acids were present at the C- but not at the N-terminus. Conclusion: Our multi-dipeptide quantification approach demonstrates organ-specific dipeptide distribution. This method allows us to understand more about the dipeptide metabolism in disease or in healthy state.