1.
Delignification Of Rice Husk By Organic Solvent Treatment To Increase It’s In Vitro Digestibility
by Awais Alam (2012-VA-604) | Dr. AbuSaeed Hashmi | Miss Huma Mujahid | Dr. Asif Nadeem.
Material type: ; Literary form:
not fiction
Publisher: 2014Dissertation note: The major constituent of plant cell wall is lignocellulose. Plant biomass mostly consist of cellulose, hemicellulose and lignin alongside little measures of pectin, protein, extractives (dissolvable nonstructural materials, for example, sugars, nitrogenous material, chlorophyll, waxes) and ash. Lignocellulosic biomass is the most abundant organic material in nature. There is an expected yearly overall production of 10–50 billion dry tons representing about 50% of the worldwide biomass yield (Parveen et al. 2009).
Numerous physicochemical, structural and compositional variables decrease the digestibility of cellulose present in lignocellulosic material. So a treatment is required to increase the digestibility of lignocellulose biomass by exposing the cellulose present in plant fibers. Different techniques have been utilized for treatment, including chemical treatment, ammonia fiber explosion, biological treatment and steam explosion to modify the cellulosic structure to increase the availability of cellulose for digestion (Haoran et al. 2013). At that point, acids, bases and enzymes might be utilized to break down the cellulose into its respective sugars. Cellulolytic enzymesare broadly used to break down cellulose into its constituent sugars.
Among various agricultural wastes a broadly available waste is Rice husk (RH) which is rich in lignocellulosic material. Internationally, roughly 600 million tons of rice paddy is delivered every year. By and large 20% of the rice paddy is husk, giving a yearly aggregate generation of 120 million tons (Abbas et al. 2010). Pakistan is a rice producing country a great part of the husk produced from processing of rice is either blazed or dumped as waste. Rice husk yield in Pakistan is more than 1780 thousand tons every year (Asif et al. 2013).
Rice husk produced during rice refining, makes disposal issue because of less business interest. Additionally, handling and transportation of RH is hazardous because of its low density. Rice husk ash (RHA) is an incredible environmental risk bringing about harm to land and encompassing range here it is dumped. Thus, business utilization of rice husk and its ash is the option answer for disposal problem (Dilip et al. 2014).
RH are essentially made up of lignocellulose (60wt. %) and silica (11wt. %). The greater part of past investigations concentrated on the preparation of silica or other silicon based materials from RH, while the lignocellulose in RH was mostly glazed and then wasted. Thus, a methodology for comprehensive usage of RH has been produced to expand its digestibility by the breakdown of lignocellulosic mass. (Ajay et al. 2012)
Numerous techniques have been adopted for treating lignocellulosic feedstocks. However just a few of them appear to be encouraging. These treatment techniques include dilute acid treatment, steam blast (CO2 blast), pH controlled water treatment, ammonia fiber expension, ammonia recycle percolation (ARP) and lime treatment. Some survey articles have been appeared for microbial biomass treatment. But the present study gave presentations on organosolv treatment process. Despite the fact that organosolv treatment is more expensive at present than the leading treatment forms, it can give some significant side products. It appears that organosolv treatment is more practical for biorefinery of lignocellulosic biomass which considers the usage of every bit of biomass parts. An essential streamlining and usage of side products may lead the organosolv treatment to be a guaranteeing one for bio refining lignocellulosic feedstock in future. Organosolv treatment yields three different parts: dry lignin, a watery hemicellulose stream and a moderately pure cellulose division (Xuebing et al. 2009).
Availability: Items available for loan: UVAS Library [Call number: 2230-T] (1).
2.
Sequence Analysis Of Mitochondrial Atpase 8/6 Gene Variants In Equine
by Kashif Hameed Anjum (2012-VA-905) | Dr. Asif Nadeem | Mr.Maryam Javed | Dr. Muhammad Tayyab.
Material type: ; Literary form:
not fiction
Publisher: 2014Dissertation note: Human has been using horses for doing different jobs like transportation, hunts, carrying loads, warfare and sports (Zhang et al. 2012). In Pakistan, horses and donkeys are mostly used for transportation whilehorses are also used for racing and playing games like polo.There are two main types of horses:Equuscaballusare domesticated horses and Equusferus are the wild horses. There are more than 300 breeds of horses in the world today (Barbara and Dafydd, 2007). The horse population is estimated as 0.32 million and has been decreasing over the years in Pakistan. Main breeds of horses that are found all over the Pakistan are Kajlan, Kakka, Balochi, Morna, Shien, Anmol, Makra, Pak-thoroughbred,Heerzaiand Waziri (Khan, 2004).
Seventy percent of the population earns living from the land. Agriculture contributes nearly 21% to gross domestic product and generates 43% of all jobs. Over 30 million people in rural areas derive their livelihood from livestock production. The number of impoverished communities moving from the country to find work in Pakistan’s towns and cities is rising. Many of these people rely on working equine animals to earn a living.
Nuclear and mitochondrial genomes are frequently used in animal genetic research. Nuclear genomeis generally a huge and complicated molecule and is not well studied in many species. However mitochondrial DNA being small sized and having high mutation rate is used frequently for the purpose of genetic research (Stanley et al. 1994). Characteristic of having fast evolution rate as compared to nuclear DNA makes mitochondrial genes a good tool for genetic studies (Avise, 1994).
Several studies have investigated the genetic relationship among horse and donkey breeds using mitochondrial sequences as a marker for breed characterization and phylogenetic. Each mitochondrion contains its own circular DNA, replication, transcription and translation machinery and serves as semi-autonomous organelle. Mitochondria perform so many important functions in our body like metabolism(oxidative phosphorylation), apoptosis and aging(Weinberg, 2007).
The advent ofpolymerase chain reaction and direct sequencing techniques with the use of mtDNA as a phylogenetic marker has been extended to much greater levels of phylogenetic inclusiveness (Zardoya and Meyer,1996). The special features of mtDNAi-e,lack of introns, maternal inheritance, absence of recombination events and haploidy have made it the most common type of sequence information used to estimate phylogenies among both closely and distantly related texa(Meyer, 1993).
Four of the five mitochondrial respiratory chain complexes, namely C1, C3, C4 and C5 (ATP synthase) contain subunits encoded by mitochondrial DNA (Kadenbach, 2012). ATP synthase (Complex5) functions to make ATP that is used by the cell (Von et al. 2009). ATP synthasecomprisesan integral membrane cylindrical, the F0 particle and a peripheral matrix-facing F1 particle, the catalytic ATP synthase domain (Boyer, 1997). All aerobically respiring organisms possess ATP synthase enzymes and are located inthe cell membrane in prokaryotes, the mitochondrial inner membrane in eukaryotes and the chloroplast thylakoid membrane (Ackerman and Tzagoloff, 2005). This enzyme is responsible for the final step of oxidative phosphorylation. The protons move down their concentration gradient from inter membrane space to matrix through F0 particle while F1particleuses the energy provided by influx of these protons and converts ADP molecule into ATP. ATPase 6 and ATPase 8 proteins are components of F0 particle where they play direct role in maintaining the structure and function of ATP synthase (complex 5). All five subunits of F1 and most of the F0 subunits are nuclear encoded(Collinson et al. 1996). Only two proteins i-e, ATPase 6 and ATPase 8 are encoded by mtDNA (Boyer, 1993).
The present study is designed to investigate the diversity and phylogenetic analysis of Thoroughbred Pakistani horse and donkey breeds on the basis of ATPase 6 and ATPase 8 genes.
Availability: Items available for loan: UVAS Library [Call number: 2236-T] (1).
3.
Molecular Exploration Of Zinc Finger Bed-Type Containing 6 Gene For Growth Trait In Beetal Goat
by Kanwal Rashid (2014-VA-496) | Dr. Maryam Javed | Dr. Asif Nadeem | Dr. Abu Saeed Hashmi.
Material type: ; Literary form:
not fiction
Publisher: 2016Dissertation note: Zinc finger, BED-type containing 6 (ZBED6), is a novel transcription factor.It acts as a repressor of IGF2 transcription in skeletal muscle myogenesis and development. it is mainly involved in organism development, signaling, cell to cell interaction, hepatic fibrosis, clathrin mediated endocytosis and tight junction signaling cascades. Chromatin immunoprecipitation (ChIP) sequencing using C2C12 cells identified about 2,500 ZBED6 binding sites in the genome, and the deduced consensus motif gave a perfect match with the established binding site in Igf2. Silencing of Zbed6 in myoblast cells affect Igf2 expression, cell proliferation, wound healing, and myotube formation. Genes associated with ZBED6 binding sites showed a highly significant enrichment for certain Gene Ontology classifications, including development and transcriptional regulation.Functional and signaling assays of BED6 gene indicate its probable role in controlling growth traits in Goat. Blood samples (n = 40) were collected. Inorganic method of DNA extraction used. Primers for PCR amplification will be designed using Primer3 software. PCR products will be sequenced bi-directionally on ABI 3130XL Genetic analyzer. The results of sequencing were analyzed using CHROMAS software. Sequence alignment tools (blast 2)were used for SNPs identification. Difference between allele and genotype frequency of studied gene evaluated by chi square test, likelihood test and analysis was done by POPGENE and one way ANOVA.Novel Variations identified which have probable implementation in selection of superior goats with higher tendencies towards weight gain. Availability: Items available for loan: UVAS Library [Call number: 2554-T] (1).
4.
Molecular Phylogeny And Diversity Analysis Of Bovidae (Boselaphus Tragocamelus, Antilope Cervicapra) And Cervidae (Axis Axis, Axis Porcinus) In Pakistan
by Ghulam Abbas (2011-VA-748) | Dr. Asif Nadeem | Prof. Dr. Mansoor Ellahi Babar | Dr. Muhammad Tayyab.
Material type: ; Literary form:
not fiction
Publisher: 2016Dissertation note: Many species of mammals have declined within the past two centuries due to human
caused disturbances and the unsustainable use of natural resources. Molecular methods have an
important role in phylogeny and diversity analysis. The present study was designed for diversity
analysis of Boselaphus tragocamelus & Antelope cervicapra (Bovidae) and Axis axis & Axis
porcinus (Cervidae) family in Pakistan. A total of 25 samples from each of the four species were
collected from different parks, zoos and natural habitats. DNA was extracted, PCR primers were
designed and cytochrome-b, cytochrome-c gene and d-loop regions were amplified by PCR.
PCR products were sequenced bi-directionally by Big DyeTM Terminator. Bioinformatics tools,
Blast 2 sequences, Clustal-W, MEGA-6, Bioconductor in “R” were applied for analysis. The
clustering of the samples indicates that each species contains less within-population genetic
variability. Same pattern was observed when sequence of three genes was combined and MDS
plot was constructed. Phylogenetic analysis of the gene sequences revealed that each species
comprised a clade that is clearly distinct from the clade comprised of other species of deer
selected for this study. Finding of this study indicated that these species of deer have significant
genetic variations among-species that differentiate them from each other. This is the first report
from our region. The information of selected species of deer is prerequisite for designing
effective strategy in future conservation practices. However further genomic investigations
should be carried out at larger scale. Availability: Items available for loan: UVAS Library [Call number: 2560-T] (1).
5.
Molecular Investigation Of Low Density Lipoprotein Receptor Gene Causing Familial Hypercholesterolemia And Its Evolutionary Relationship With Pan Troglodytes
by Rida Zainab (2014-VA-808) | Dr. Maryam Javed | Dr. Asif Nadeem | Prof. Dr. Tahir Yaqub.
Material type: ; Literary form:
not fiction
Publisher: 2016Dissertation note: Familial Hypercholesterolemia (FH) phenotype is related to improper metabolism of low density lipoproteins due to mutations in Low-density lipoprotein receptor (LDLR) gene with increased risk of ischemic heart disease. Genetic variants in LDLR gene are associated with defective catabolism of cholesterol effecting lipid metabolism which results in familial hypercholesterolemia. It occurs in both forms: Homozygous Familial Hypercholesterolemia and Heterozygous Familial Hypercholesterolemia.
Patients having high cholesterol were identified by observing the values of their serum lipid profile test reports. Their detailed history was taken and blood samples from the identified patients of familial hypercholesterolemia were collected. DNA extraction was done by Organic method. Primers were synthesized and PCR was conducted using optimized recipe and conditions. PCR products were sequenced.
Sequenced data was analyzed using Chromas or BioEdit software. BLAST was performed and sequences were aligned individually by comparing it to the reference sequence. This showed difference in any specific position of a mutated sequence against the reference sequence. CLUSTALW aligned all the sequences together in one time. Sequences were compared with reference sequence to detect the presence of any mutation or SNPs.
SNPs were identified manually and the peaks were observed in order to determine if the genotype is heterozygous or homozygous. Statistical Analysis was done and any amino acid change due to the observed SNPs was determined by using Expasy Translate Tool. It was found that both the SNPs showed amino acid changes. In the end, homology analysis was done which showed that Homo sapiens had their LDLR gene closest to that of Gorilla gorilla gorilla. Availability: Items available for loan: UVAS Library [Call number: 2551-T] (1).
