145 research outputs found
Fiber Metabolism, Procollagen and Collagen Type III Immunoreactivity in Broiler Pectoralis Major Affected by Muscle Abnormalities
The present study aimed to evaluate the muscle fiber metabolism and assess the presence and distribution of both procollagen and collagen type III in pectoralis major muscles affected by white striping (WS), wooden breast (WB), and spaghetti meat (SM), as well as in those with macroscopically normal appearance (NORM). For this purpose, 20 pectoralis major muscles (five per group) were selected from the same flock of fast-growing broilers (Ross 308, males, 45-days-old, 3.0 kg live weight) and were used for histochemical (nicotinamide adenine dinucleotide tetrazolium reductase (NADH-TR) and alpha-glycerophosphate dehydrogenase (\u3b1-GPD)) and immunohistochemical (procollagen and collagen type III) analyses. When compared to NORM, we found an increased proportion (p < 0.001) of fibers positively stained to NADH-TR in myopathic muscles along with a relevant decrease (p < 0.001) in the percentage of those exhibiting a positive reaction to \u3b1-GPD. In addition, an increased proportion of fibers exhibiting a positive reaction to both stainings was observed in SM, in comparison with NORM (14.3 vs. 7.2%; p < 0.001). After reacting to NADH-TR, SM exhibited the lowest (p < 0.001) cross-sectional area (CSA) of the fibers ( 1212% with respect to NORM). On the other hand, after reacting to \u3b1-GPD, the CSA of WS was found to be significantly larger (+10%) in comparison with NORM (7480 vs. 6776 \ub5m2; p < 0.05). A profound modification of the connective tissue architecture involving a different presence and distribution of procollagen and collagen type III was observed. Intriguingly, an altered metabolism and differences in the presence and distribution of procollagen and collagen type III were even observed in pectoralis major muscle classified as NORM
Effects of Bioactive Peptides from Atlantic Salmon Processing By-Products on Oxyntopeptic and Enteroendocrine Cells of the Gastric Mucosa of European Seabass and Gilthead Seabream
The present study was designed to evaluate the effects of dietary levels of bioactive peptides (BPs) derived from salmon processing by-products on the presence and distribution of peptic cells (oxyntopeptic cells, OPs) and enteric endocrine cells (EECs) that contain GHR, NPY and SOM in the gastric mucosa of European seabass and gilthead seabream. In this study, 27 seabass and 27 seabreams were divided into three experimental groups: a control group (CTR) fed a control diet and two groups fed different levels of BP to replace fishmeal: 5% BP (BP5%) and 10% BP (BP10%). The stomach of each fish was sampled and processed for immunohistochemistry. Some SOM, NPY and GHR-IR cells exhibited alternating âopen typeâ and âclosed typeâ EECs morphologies. The BP10% group (16.8 ± 7.5) showed an increase in the number of NPY-IR cells compared to CTR (CTR 8.5 ± 4.8) and BP5% (BP10% vs. CTR p †0.01; BP10% vs. BP5% p †0.05) in the seabream gastric mucosa. In addition, in seabream gastric tissue, SOM-IR cells in the BP 10% diet (16.8 ± 3.5) were different from those in CTR (12.5 ± 5) (CTR vs. BP 10% p †0.05) and BP 5% (12.9 ± 2.5) (BP 5% vs. BP 10% p †0.01). EEC SOM-IR cells increased at 10% BP (5.3 ± 0.7) compared to 5% BP (4.4 ± 0.8) (5% BP vs. 10% BP p †0.05) in seabass. The results obtained may provide a good basis for a better understanding of the potential of salmon BPs as feed ingredients for seabass and seabream.publishedVersio
Expression and regulation of α-transducin in the pig gastrointestinal tract
Taste signalling molecules are found in the gastrointestinal (GI) tract suggesting that they participate to chemosensing. We tested whether fasting and refeeding affect the expression of the taste signalling molecule, a-transducin (Gatran), throughout the pig GI tract and the peptide content of Gatran cells. The highest density of Gatran-immunoreactive (IR) cells was in the pylorus, followed by the cardiac mucosa, duodenum, rectum, descending colon, jejunum, caecum, ascending colon and ileum. Most Gatran-IR cells contained chromogranin A. In the stomach, many Gatran-IR cells contained ghrelin, whereas in the upper small intestine many were gastrin/cholecystokinin-IR and a few somatostatin-IR. Gatran-IR and Gagust-IR colocalized in some cells. Fasting (24 h) resulted in a significant decrease in Gatran-IR cells in the cardiac mucosa (29.3 0.8 versus 64.8 1.3, P < 0.05), pylorus (98.8 1.7 versus 190.8 1.9, P < 0.0 l), caecum (8 0.01 versus 15.5 0.5, P < 0.01), descending colon (17.8 0.3 versus 23 0.6, P < 0.05) and rectum (15.3 0.3 versus 27.5 0.7, P < 0.05). Refeeding restored the control level of Gatran-IR cells in the cardiac mucosa. In contrast, in the duodenum and jejunum, Gatran-IR cells were significantly reduced after refeeding, whereas Gatran-IR cells density in the ileum was not changed by fasting/refeeding. These findings provide further support to the concept that taste receptors contribute to luminal chemosensing in the GI tract and suggest they are involved in modulation of food intake and GI function induced by feeding and fasting
Quali-quantitative evaluation of ileal peyer's patches innervation in scrapie-free or scrapie-affected sarda breed ovines
Although Peyer's patches (PPs) and the enteric nervous system (ENS) play a key role in early sheep scrapie
pathogenesis, little is known on the kinetics of ENS plexuses colonization.
This study was aimed at quali-quantitatively evaluating ileal PP innervation in 29 Sarda breed ovines (12 scrapie-free, 2
months-old lambs, 4 ARQ/ARQ, 4 ARR/ARQ and 4 ARR/ARR, respectively; 12 scrapie-free, 2-4 years-old sheep, 3
ARQ/ARQ, 7 ARR/ARQ and 2 ARR/ARR, respectively; 5 ARQ/ARQ scrapie-affected sheep)
The evolution of vimentin and desmin in Pectoralis major muscles of broiler chickens supports their essential role in muscle regeneration
Vimentin (VIM) and desmin (DES) are muscle-specific proteins having crucial
roles in maintaining the lateral organization and alignment of the sarcomeric
structure during myofibrilsâ regeneration. The present experiment was designed
to ascertain the evolution of VIM and DES in Pectoralis major muscles (PM) of
fast-growing (FG) and medium-growing (MG) meat-type chickens both at the
protein and gene levels. MG broilers were considered as a control group
whereas the evolution of VIM and DES over the growth period was
evaluated in FG by collecting samples at different developmental stages (7,
14, 21, 28, 35, and 42 days). After performing a preliminary classification of the
samples based on their histological features, 5 PM/sampling time/genotype
were selected for western blot, immunohistochemistry (IHC), and gene
expression analyses. Overall, the findings obtained at the protein level
mirrored those related to their encoding genes, although a potential time
lag required to observe the consequences of gene expression was evident.
The two- and 3-fold higher level of the VIM-based heterodimer observed in FG
at d 21 and d 28 in comparison with MG of the same age might be ascribed to
the beginning and progressive development of the regenerative processes. This
hypothesis is supported by IHC highlighting the presence of fibers to coexpressing
VIM and DES. In addition, gene expression analyses suggested
that, unlike VIM common sequence, VIM long isoform may not be directly
implicated in muscle regeneration. As for DES content, the fluctuating trends
observed for both the native protein and its heterodimer in FG might be
ascribed to its importance for maintaining the structural organization of the
regenerating fibers. Furthermore, the higher expression level of the DES gene in
FG in comparison with MG further supported its potential application as a
marker of muscle fibersâ regeneration. In conclusion, the findings of the present
research seem to support the existence of a relationship between the
occurrence of muscle regeneration and the growth rate of meat-type chickens and corroborate the potential use of VIM and DES as molecular
markers of these cellular processes
Distribution of α-transducin and α-gustducin immunoreactive cells in the chicken (Gallus domesticus) gastrointestinal tract
The expression and distribution patterns of the taste signaling molecules, α-gustducin (Gαgust) and α-transducin (Gαtran) G-protein subunits, were studied in the gastrointestinal tract of the chicken (Gallus domesticus) using the immunohistochemical method. Gαgust and Gαtran immunoreactive (-IR) cells were observed in the mucosal layer of all examined segments, except the esophagus, crop, and the saccus cranialis of the gizzard. The highest numbers of Gαgust and Gαtran-IR cells were found in the proventriculus glands and along the villi of the pyloric, duodenum, and rectal mucosa. Gαgust and Gαtran-IR cells located in the villi of the jejunum, ileum, and cloaca were much less numerous, while only a few Gαgust and Gαtran-IR cells were detected in the mucosa of the proventriculus and cecum. In the crypts, IR cells were observed in the small and large intestine as well as in the cloaca. Gαgust and Gαtran-IR cells displayed elongated ("bottle-" or "pear-like") or rounded shape. The demonstration of Gαgust and Gαtran expression provides evidence for taste receptor mediated mucosal chemosensitivity in the chicken gastrointestinal tract
Novel understanding on genetic mechanisms of enteric neuropathies leading to severe gut dysmotility
The enteric nervous system (ENS) is the third division of the autonomic autonomic nervous system and the largest collection of neurons outside the central nervous system (CNS). The ENS has been referred to as "the brain in the gut" or "the second brain of the human body" because of its highly integrated neural circuits controlling a vast repertoire of gut functions, including absorption/secretion, splanchnic blood vessels, some immunological aspects, intestinal epithelial barrier, and gastrointestinal (GI) motility. The latter function is the result of the ENS fine-tuning over smooth musculature, along with the contribution of other key cells, such as enteric glia (astrocyte like cells supporting and contributing to neuronal activity), interstitial cells of Cajal (the pacemaker cells of the GI tract involved in neuromuscular transmission), and enteroendocrine cells (releasing bioactive substances, which affect gut physiology). Any noxa insult perturbing the ENS complexity may determine a neuropathy with variable degree of neuro-muscular dysfunction. In this review, we aim to cover the most recent update on genetic mechanisms leading to enteric neuropathies ranging from Hirschsprung's disease (characterized by lack of any enteric neurons in the gut wall) up to more generalized form of dysmotility such as chronic intestinal pseudo-obstruction (CIPO) with a significant reduction of enteric neurons. In this line, we will discuss the role of the RAD21 mutation, which we have demonstrated in a family whose affected members exhibited severe gut dysmotility. Other genes contributing to gut motility abnormalities will also be presented. In conclusion, the knowledge on the molecular mechanisms involved in enteric neuropathy may unveil strategies to better manage patients with neurogenic gut dysmotility and pave the way to targeted therapies
Pathogenetic investigations on the enteric nervous system plexuses of sarda breed sheep with different PrP genotypes following oral experimental scrapie infection
We investigated the ileal myenteric (MPs) and submucosal plexuses (SMPs) of 32 Sarda breed sheep carrying
different PrP genotypes (ARQ/ARQ, ARQ/AHQ, ARQ/ARR, ARR/ARR), which had been orally dosed with
scrapie at 8 months of age and euthanized at definite time intervals post-infection (p.i.)
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