Tissue heterogeneity of mitochondrial activity, biogenesis and mitochondrial protein gene expression in buffalo

Effect of glutathione addition on vitrification of ovine oocytes

The exogenous antioxidants are commonly employed to mitigate vitrification-induced oxidative damage. Glutathione (GSH), a vital antioxidant, plays a significant role in scavenging free radicals, providing antioxidant protection, and maintaining cellular integrity. This study aimed to investigate the effects of GSH supplementation on the vitrification of ovine oocytes. To identify the optimal concentration of exogenous GSH supplementation, the impacts of 2 mM, 4 mM, and 8 mM GSH on the survival and fragmentation of oocytes were evaluated after vitrification. In addition, immunofluorescence (IF) staining was employed to evaluate spindle morphology, chromosome distribution, cortical granule distribution, mitochondrial function, and reactive oxygen species (ROS) levels. The levels of ATP and NADPH, along with the ratio of GSH/GSSH, were also examined. Additionally, evaluations of in vitro fertilization were carried out. The results of oocyte survival rates and fragmentation rates identified that the addition of 4 mM GSH to the vitrification solution was the optimal concentration. The assessment of spindle morphology, chromosome distribution, cortical granule distribution, mitochondrial function, ROS production, ATP activity, and NADPH levels, as well as the GSH/GSSH ratio, confirm the beneficial effect of GSH supplementation against the vitrification-induced oxidative damage. Lastly, incorporating GSH into the vitrification process enhanced the developmental potential of oocytes, resulting in higher cleavage rates, increased blastocyst rates, and improved quality of blastocysts. Overall, this research uncovered the mechanisms through which GSH mitigates the oxidative damage induced by vitrification, thereby leading to the optimization of the vitrification technique for ovine oocytes.

Nuclear Genome-Encoded Mitochondrial OXPHOS Complex I Genes in Female Buffalo Show Tissue-Specific Differences

Buffalo physiology intricately balances energy, profoundly influencing health, productivity, and reproduction. This study explores nuclear-mitochondrial crosstalk, revealing OXPHOS Complex I gene expression variations in buffalo tissues through high-throughput RNA sequencing. Unveiling tissue-specific disparities, the research elucidates the genomic landscape of crucial energy production genes, with broader implications for veterinary and agricultural progress. Post-slaughter, tissues from post-pubertal female buffaloes underwent meticulous processing and RNA extraction using the TRIzol method. RNA-Seq library preparation and IlluminaHiSeq 2500 sequencing were performed on QC-passed samples. Data underwent stringent filtration, mapping to the Bubalus bubalis genome using HISAT2. DESeq2 facilitated differential expression gene (DEG) analysis focusing on 57 Mitocarta 3-derived genes associated with OXPHOS complex I. Nuclear-encoded mitochondrial protein transcripts of OXPHOS complex 1 exhibited tissue-specific variations, with 51 genes expressing significantly across tissues. DEG analysis emphasized tissue-specific expression patterns, highlighting a balanced OXPHOS complex I subunit expression in the kidney vs. brain. Gene Ontology (GO) enrichment showcased mitochondria-centric terms, revealing distinct proton motive force-driven mitochondrial ATP synthesis regulation. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analyses emphasized Thermogenesis and OXPHOS pathways, enriching our understanding of tissue-specific energy metabolism. Noteworthy up-regulation of NDUFB10 in the heart and kidney aligned with heightened metabolic activity. Brain-specific up-regulation of NDUFAF6 indicated a focus on mitochondrial function, while variations in NDUFA11 and ACAD9 underscored pivotal roles in the heart and kidney. GO and KEGG analyses highlighted tissue-specific mitochondrial ATP synthesis and NADH dehydrogenase processes, providing molecular insights into organ-specific metabolic demands and regulatory mechanisms. Our study unveils conserved and tissue-specific nuances in nuclear-encoded mitochondrial OXPHOS complex I genes, laying a foundation for understanding diverse energy demands and potential health implications.

MitoSNO inhibits mitochondrial hydrogen peroxide (mtH2O2) generation by α-ketoglutarate dehydrogenase (KGDH)

Here, we demonstrate mitochondrial hydrogen peroxide (mtH2O2) production by α-ketoglutarate dehydrogenase (KGDH) can be inhibited by MitoSNO, alleviating lipotoxicity. MitoSNO in the nanomolar range inhibits mtH2O2 by ∼50% in isolated liver mitochondria without disrupting respiration, whereas the mitochondria-selective derivative used to synthesize MitoSNO, mitochondria-selective N-acetyl-penicillamine (MitoNAP), had no effect on either mtH2O2 generation or oxidative phosphorylation (OxPhos). Additionally, mtH2O2 generation in isolated liver mitochondria was almost abolished when MitoSNO was administered in the low micromolar range. The potent inhibitory effect of MitoSNO was comparable to 2-keto-3-methyl-valeric acid (KMV) and valproic acid (VA), selective inhibitors for KGDH-mediate mH2O2 production. S1QEL 1.1 (S1) and S3QEL (S3), which are known to selectively suppress mtH2O2 genesis through inhibition of complex I and complex III respectively, without disrupting respiration, had little to no effect on mtH2O2 production by liver mitochondria. We also identified it was a major mtH2O2 source as well but MitoSNO and MitoNAP did not affect mtH2O2 production by this ETC-linked enzyme. The MitoSNO also suppressed mtH2O2 production and partially rescued mitochondrial respiration in Huh-7 cells subjected to palmitate (PA) and fructose (Fruc) induced lipotoxicity. MitoSNO also prevented cell death and abrogated intrahepatic lipid accumulation in these Huh-7 cells. MitoSNO nullified mtH2O2 overgeneration and partially rescued OxPhos in liver mitochondria from mice fed a high fat diet (HFD). Our findings demonstrate that MitoSNO interferes with mtH2O2 production through KGDH S-nitrosation and may be useful in alleviating non-alcoholic fatty liver disease (NAFLD).

Exploring the interplay between mitochondrial dysfunction, early life adversity and bipolar disorder

OBJECTIVE

Mitochondria are essential for energy production and reactive oxygen species (ROS) generation, with changes in ROS levels or energy demands affecting mitochondrial DNA (mtDNA) copy numbers, indicating mitochondrial function. Early life adversity (ELA) affects mitochondrial dynamics, influencing long-term health. Both ELA and mitochondrial abnormalities have been independently associated with bipolar disorder (BD). This study aims to explore the complex interplay between mitochondrial dysfunction, ELA, and BD.

METHODS

The study included 60 participants diagnosed with BD and 66 healthy controls (HCs). Data were collected using the Childhood Trauma Questionnaire (CTQ), and leukocyte mtDNA copy number (MCN) was determined from blood samples.

RESULTS

The results indicated the CTQ sum scores were significantly higher in the BD group, reflecting greater exposure to ELA. In HCs, a marginally significant nonlinear relationship between the square of the CTQ sum score and MCN was found. Further analysis demonstrated a significant interaction between ELA and BD on MCN (p = 0.023), highlighting a critical connection between ELA and mitochondrial dysfunction in BD and reinforcing its biological underpinnings.

CONCLUSIONS

Future treatments for BD might target mitochondrial dysfunctions related to chronic stress, with potential pharmaceuticals designed to address these issues and mitigate the negative effects of chronic stress.

Unveiling the tissue-specific landscape of nuclear-encoded mitochondrial genes involved in amino acid metabolism in buffalo

Mitochondria play a pivotal role in energy production, metabolism, and cellular signaling, serving as key regulators of cellular functions, including differentiation and tissue-specific adaptation. The interplay between mitochondria and the nucleus is crucial for coordinating these processes, particularly through the supply of metabolites for epigenetic modifications that facilitate nuclear-mitochondrial interactions. To investigate tissue-specific mitochondrial adaptations at the molecular level, we conducted RNA sequencing data analyses of kidney, heart, brain, and ovary tissues of female buffaloes, focusing on variations in mitochondrial gene expression related to amino acid metabolism. Our analysis identified 82 nuclear-encoded mitochondrial transcripts involved in amino acid metabolism, with significant differential expression patterns across all tissues. Notably, the heart, brain, and kidney-tissues with higher energy demands-exhibited elevated expression levels compared to the ovary. The kidney displayed unique gene expression patterns, characterized by up-regulation of genes involved in glyoxylate metabolism and amino acid catabolism. In contrast, comparative analysis of the heart and kidney versus the brain revealed shared up-regulation of genes associated with fatty acid oxidation. Gene ontology and KEGG pathway analyses confirmed the enrichment of genes in pathways related to amino acid degradation and metabolism. These findings highlight the tissue-specific regulation of mitochondrial gene expression linked to amino acid metabolism, reflecting mitochondrial adaptations to the distinct metabolic and energy requirements of different tissues in buffalo. Importantly, our results underscore the relevance of mitochondrial adaptations not only for livestock health but also for understanding metabolic disorders in humans. By elucidating the molecular mechanisms of mitochondrial function and their tissue-specific variations, this study provides insights that could inform breeding strategies for enhanced livestock productivity and contribute to therapeutic approaches for human metabolic diseases. Thus, our findings illustrate how mitochondria are specialized in a tissue-specific manner to optimize amino acid utilization and maintain cellular homeostasis, with implications for both animal welfare and human health.

Neuroprotective Effects of Berberine Chloride Against the Aluminium Chloride-Induced Alzheimer's Disease in Zebra Fish Larvae

Alzheimer's disease (AD) is a neurodegenerative disease distinguished by cognitive and memory deficits. A lack of memory, cognition, and other forms of cognitive dissonance characterizes AD, which affects approximately 50 million people worldwide. This study aimed to identify the neuroprotective effects of berberine chloride (BC) against aluminium chloride (AlCl3)-induced AD in zebrafish larvae by inhibiting oxidative stress and neuroinflammation. BC toxicity was assessed by evaluating survival rates, malformations, and heart rates in zebrafish larvae following treatment with varying concentrations of BC. This study elucidates the mechanisms of BC through an extensive range of biochemical assays, behavioral testing, and molecular docking analysis. The developmental toxicity assessment of BC indicated that doses up to 40 μM did not cause any developmental abnormalities until 96 h post fertilization. The LC50 value of BC in zebrafish larvae was found to be 50.16 μM. The biochemical and behavioral changes induced by AlCl3 in zebrafish larvae were significantly mitigated by BC treatment. Our findings demonstrate that BC can reduce total cholesterol and triglyceride levels in AlCl3-induced AD zebrafish larvae. Our molecular docking results indicated that BC significantly interacted with the ABCA1 protein, suggesting that BC may act as an ABCA1 agonist. Based on our results, it can be concluded that BC may serve as an effective therapeutic agent for mitigating oxidative stress by altering cholesterol metabolism in AlCl3-induced AD.

Tissue-Specific Diversity of Nuclear-Encoded Mitochondrial Genes Related to Lipid and Carbohydrate Metabolism in Buffalo

Buffaloes play a crucial role in Asian agriculture, enhancing food security and rural development. Their distinct metabolic needs drive tissue-specific mitochondrial adaptations, regulated by both mitochondrial and nuclear genomes. This study explores how nuclear-encoded mitochondrial genes involved in lipid and carbohydrate metabolism vary across tissues-an area with significant implications for buffalo health, productivity, and human health. We hypothesize that tissue-specific variations in metabolic pathways are reflected in the expression of nuclear-encoded mitochondrial genes, which are tailored to the metabolic needs of each tissue. We utilized high-throughput RNA sequencing (RNA-seq) data to assess the expression of nuclear-encoded mitochondrial genes related to lipid and carbohydrate metabolism across various tissues in healthy female buffaloes aged 3-5 years, including the kidney, heart, brain, and ovary. Differential expression analysis was performed using DESeq2, with significance set at p < 0.05 for Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway analyses. A total of 164 genes exhibited tissue-specific regulation, with the heart and brain, which have higher energy demands, expressing more genes than the kidney and ovary. Notably, the comparison between the kidney and ovary showed the highest number of differentially expressed genes. Interestingly, the kidney up-regulates gluconeogenesis-related genes (e.g., PCK2, PCCA, LDHD), promoting glucose production, while these genes are down-regulated in the ovary. In contrast, the brain up-regulates pyruvate metabolism genes (e.g., PCCA, PDHA1, LDHD), underscoring its reliance on glucose as a primary energy source, while these genes are down-regulated in the ovary. The higher abundance of EHHADH in the brain compared to the ovary further emphasizes the critical role of fatty acid metabolism in brain function, aligned with the brain's high energy demands. Additionally, down-regulation of the StAR gene in both the kidney versus ovary and brain versus ovary comparisons suggests tissue-specific differences in steroid hormone regulation. These findings highlight tissue-specific variations in nuclear-encoded mitochondrial genes related to lipid and carbohydrate metabolism, reflecting adaptations to each tissue's unique metabolic needs. This study lays a foundation for advancing mitochondrial metabolism research in livestock, with significant implications for human health. Insights could inform dietary or therapeutic strategies for metabolic disorders, such as cardiovascular diseases and metabolic syndrome, while also enhancing livestock productivity.

Differential Expression of Nuclear-Encoded Mitochondrial Protein Genes of ATP Synthase Across Different Tissues of Female Buffalo

The physiological well-being of buffaloes, encompassing phenotypic traits, reproductive health, and productivity, depends on their energy status. Mitochondria, the architects of energy production, orchestrate a nuanced interplay between nuclear and mitochondrial domains. Oxidative phosphorylation complexes and associated proteins wield significant influence over metabolic functions, energy synthesis, and organelle dynamics, often linked to tissue-specific pathologies. The unexplored role of ATP synthase in buffalo tissues prompted a hypothesis: in-depth exploration of nuclear-derived mitochondrial genes, notably ATP synthase, reveals distinctive tissue-specific diversity. RNA extraction and sequencing of buffalo tissues (kidney, heart, brain, and ovary) enabled precise quantification of nuclear-derived mitochondrial protein gene expression. The analysis unveiled 24 ATP synthase transcript variants, each with unique tissue-specific patterns. Kidney, brain, and heart exhibited elevated gene expression compared to ovaries, with 10, 8, and 19 up-regulated genes, respectively. The kidney showed 3 and 12 down-regulated genes compared to the brain and heart. The heart-brain comparison highlighted ten highly expressed genes in ATP synthase functions. Gene ontology and pathway analyses revealed enriched functions linked to ATP synthesis and oxidative phosphorylation, offering a comprehensive understanding of energy production in buffalo tissues. This analysis enhances understanding of tissue-specific gene expression, emphasizing the influence of energy demands. Revealing intricate links between mitochondrial gene expression and tissue specialization in buffaloes, it provides nuanced insights into tissue-specific expression of nuclear-encoded mitochondrial protein genes, notably ATP synthase, advancing the comprehension of buffalo tissue biology.

Metabolic reprogramming via mitochondrial delivery for enhanced maturation of chemically induced cardiomyocyte-like cells

Heart degenerative diseases pose a significant challenge due to the limited ability of native heart to restore lost cardiomyocytes. Direct cellular reprogramming technology, particularly the use of small molecules, has emerged as a promising solution to prepare functional cardiomyocyte through faster and safer processes without genetic modification. However, current methods of direct reprogramming often exhibit low conversion efficiencies and immature characteristics of the generated cardiomyocytes, limiting their use in regenerative medicine. This study proposes the use of mitochondrial delivery to metabolically reprogram chemically induced cardiomyocyte-like cells (CiCMs), fostering enhanced maturity and functionality. Our findings show that mitochondria sourced from high-energy-demand organs (liver, brain, and heart) can enhance structural maturation and metabolic functions. Notably, heart-derived mitochondria resulted in CiCMs with a higher oxygen consumption rate capacity, enhanced electrical functionality, and higher sensitivity to hypoxic condition. These results are related to metabolic changes caused by increased number and size of mitochondria and activated mitochondrial fusion after mitochondrial treatment. In conclusion, our study suggests that mitochondrial delivery into CiCMs can be an effective strategy to promote cellular maturation, potentially contributing to the advancement of regenerative medicine and disease modeling.

Differential expression of nuclear-derived mitochondrial succinate dehydrogenase genes in metabolically active buffalo tissues

BACKGROUND

Buffaloes are crucial to agriculture, yet mitochondrial biology in these animals is less studied compared to humans and laboratory animals. This research examines tissue-specific variations in mitochondrial succinate dehydrogenase (SDH) gene expression across buffalo kidneys, hearts, brains, and ovaries. Understanding these variations sheds light on mitochondrial energy metabolism and its impact on buffalo health and productivity, revealing insights into enzyme regulation and potential improvements in livestock management.

MATERIALS AND METHODS

RNA-seq data from buffalo kidney, heart, brain, and ovary tissues were reanalyzed to explore mitochondrial SDH gene expression. The expression of SDH subunits (SDHA, SDHB, SDHC, SDHD) and assembly factors (SDHAF1, SDHAF2, SDHAF3, SDHAF4) was assessed using a log2 fold-change threshold of + 1 for up-regulated and - 1 for down-regulated transcripts, with significance set at p < 0.05. Hierarchical clustering and differential expression analyses were performed to identify tissue-specific expression patterns and regulatory mechanisms, while Gene Ontology and KEGG pathway analyses were conducted to uncover functional attributes and pathway enrichments across different tissues.

RESULTS

Reanalysis of RNA-seq data from different tissues of healthy female buffaloes revealed distinct expression patterns for SDH subunits and assembly factors. While SDHA, SDHB, and SDHC showed variable expression across tissues, SDHAF2, SDHAF3, and SDHAF4 exhibited tissue-specific profiles. Significant up-regulation of SDHA, SDHB, and several assembly factors was observed in specific tissue comparisons, with fewer down-regulated transcripts. Gene ontology and KEGG pathway analyses linked the up-regulated transcripts to mitochondrial ATP synthesis and the respiratory electron transport chain. Notably, tissue-specific variations in mitochondrial function were particularly evident in the ovary.

CONCLUSION

This study identifies distinct SDH gene expression patterns in buffalo tissues, highlighting significant down-regulation of SDHA, SDHB, SDHC, and assembly factors in the ovary. These findings underscore the critical role of mitochondria in tissue-specific energy production and metabolic regulation, suggest potential metabolic adaptations, and emphasize the importance of mitochondrial complex II. The insights gained offer valuable implications for improving feed efficiency and guiding future research and therapies for energy metabolism disorders.

Comparative Assessment of Mitochondria Isolation Buffers for Optimizing Tissue-Specific Yields in Buffalo

INTRODUCTION

Mitochondrial studies are crucial for assessing livestock health and performance. While extensive research has been done on cattle and pigs, the influence of mitochondria in Indian buffalo remains unexplored. Therefore, in order to understand functions of mitochondria, their energy-related processes, or any additional mitochondrial traits in buffaloes, it is imperative to isolate high-yield mitochondria with purity and functionality. Mitochondria are extracted by few conventional buffers. These buffers were previously characterized for their effectiveness in isolating mitochondria from rodent and human tissues. Therefore, the present study is to assess the performance of mitochondria isolation buffers specifically in buffalo tissues.

METHODS

The study involved isolation of mitochondria from four different tissues, i.e., liver, brain, heart and muscles of slaughtered buffalo (n = 3), using: (i) Tris-Mannitol buffer (ii) Tris-Sucrose buffer, and (iii) MOPS-Sucrose buffer. Buffer efficiency in preserving high fidelity during mitochondria isolation was assessed by comparison with Cayman's MitoCheck® Mitochondrial Isolation Kit (control). Further mitochondrial purity and functionality was assessed through comparative estimation of protein concentration and marker enzyme assays, respectively.

RESULTS

Our results revealed insights into the suitability of specific buffer for functional mitochondria isolation from specific type of buffalo tissue. Notably for obtaining high quality functional mitochondria from buffalo, MOPS-Sucrose buffer appeared optimal for soft tissues (liver and brain), while Tris-Mannitol buffer was efficient for hard tissues (muscles and heart).

CONCLUSIONS

Thus, our research highlights the influence of buffer composition and tissue-specific variations in buffer effectiveness on mitochondrial activity in different tissues, leading to improved mitochondrial isolation in buffalo.

Deciphering tissue-specific expression profiles of mitochondrial genome-encoded tRNAs and rRNAs through transcriptomic profiling in buffalo

BACKGROUND

Mitochondria, essential for cellular energy production through oxidative phosphorylation (OXPHOS), integrate mt-DNA and nuclear-encoded genes. This cooperation extends to the mitochondrial translation machinery, involving crucial mtDNA-encoded RNAs: 22 tRNAs (mt-tRNAs) as adapters and two rRNAs (mt-rRNAs) for ribosomal assembly, enabling mitochondrial-encoded mRNA translation. Disruptions in mitochondrial gene expression can strongly impact energy generation and overall animal health. Our study investigates the tissue-specific expression patterns of mt-tRNAs and mt-rRNAs in buffalo.

MATERIAL AND METHODS

To investigate the expression patterns of mt-tRNAs and mt-rRNAs in different tissues and gain a better understanding of tissue-specific variations, RNA-seq was performed on various tissues, such as the kidney, heart, brain, and ovary, from post-pubertal female buffaloes. Subsequently, we identified transcripts that were differentially expressed in various tissue comparisons.

RESULTS

The findings reveal distinct expression patterns among specific mt-tRNA and mt-rRNA genes across various tissues, with some exhibiting significant upregulation and others demonstrating marked downregulation in specific tissue contexts. These identified variations reflect tissue-specific physiological roles, underscoring their significance in meeting the unique energy demands of each tissue. Notably, the brain exhibits the highest mtDNA copy numbers and an abundance of mitochondrial mRNAs of our earlier findings, potentially linked to the significant upregulation of mt-tRNAs in brain. This suggests a plausible association between mtDNA replication and the regulation of mtDNA gene expression.

CONCLUSION

Overall, our study unveils the tissue-specific expression of mitochondrial-encoded non-coding RNAs in buffalo. As we proceed, our further investigations into tissue-specific mitochondrial proteomics and microRNA studies aim to elucidate the intricate mechanisms within mitochondria, contributing to tissue-specific mitochondrial attributes. This research holds promise to elucidate the critical role of mitochondria in animal health and disease.

Neuronal Ceroid Lipofuscinosis in a Mixed-Breed Dog with a Splice Site Variant in CLN6

A 23-month-old neutered male dog of unknown ancestry presented with a history of progressive neurological signs that included anxiety, cognitive impairment, tremors, seizure activity, ataxia, and pronounced visual impairment. The clinical signs were accompanied by global brain atrophy. Due to progression in the severity of disease signs, the dog was euthanized at 26 months of age. An examination of the tissues collected at necropsy revealed dramatic intracellular accumulations of autofluorescent inclusions in the brain, retina, and cardiac muscle. The inclusions were immunopositive for subunit c of mitochondrial ATP synthase, and their ultrastructural appearances were similar to those of lysosomal storage bodies that accumulate in some neuronal ceroid lipofuscinosis (NCL) diseases. The dog also exhibited widespread neuroinflammation. Based on these findings, the dog was deemed likely to have suffered from a form of NCL. A whole genome sequence analysis of the proband's DNA revealed a homozygous C to T substitution that altered the intron 3-exon 4 splice site of CLN6. Other mutations in CLN6 cause NCL diseases in humans and animals, including dogs. The CLN6 protein was undetectable with immunolabeling in the tissues of the proband. Based on the clinical history, fluorescence and electron-microscopy, immunohistochemistry, and molecular genetic findings, the disorder in this dog was classified as an NCL resulting from the absence of the CLN6 protein. Screening the dog's genome for a panel of breed-specific polymorphisms indicated that its ancestry included numerous breeds, with no single breed predominating. This suggests that the CLN6 disease variant is likely to be present in other mixed-breed dogs and at least some ancestral breeds, although it is likely to be rare since other cases have not been reported to date.