An Interview with Topher Campbell

This Curated Spaces features an interview with Topher Campbell of rukus! archive. The rukus! archive was founded in 2005 by photographer Ajamu X and filmmaker and theatre director Topher Campbell. The archive is dedicated to collecting, preserving, and making available artistic, social, and cultural histories related to Black LGBTQ+ communities in the United Kingdom. Its intellectual origins reside in the work of Stuart Hall and British cultural studies, and the critical dialogue it establishes with both mainstream heritage practices and dominant Black and queer identity discourses.

Comprehensive genetic testing combined with citizen science reveals a recently characterized ancient MC1R mutation associated with partial recessive red phenotypes in dog

Background The Melanocortin 1 Receptor (MC1R) plays a central role in regulation of coat color determination in various species and is commonly referred to as the “E (extension) Locus”. Allelic variation of the MC1R gene is associated with coat color phenotypes EM (melanistic mask), EG (grizzle/domino) and e1–3 (recessive red) in dogs. In addition, a previous study of archeological dog specimens over 10,000 years of age identified a variant p.R301C in the MC1R gene that may have influenced coat color of early dogs. Results Commercial genotyping of 11,750 dog samples showed the R301C variant of the MC1R gene was present in 35 breeds or breed varieties, at an allele frequency of 1.5% in the tested population. We detected no linkage disequilibrium between R301C and other tested alleles of the E locus. Based on current convention we propose that R301C should be considered a novel allele of the E locus, which we have termed eA for “e ancient red”. Phenotype analysis of owner-provided dog pictures reveals that the eA allele has an impact on coat color and is recessive to wild type E and dominant to the e alleles. In dominant black (KB/*) dogs it can prevent the phenotypic expression of the K locus, and the expressed coat color is solely determined by the A locus. In the absence of dominant black, eA/eA and eA/e genotypes result in the coat color patterns referred to in their respective breed communities as domino in Alaskan Malamute and other Spitz breeds, grizzle in Chihuahua, and pied in Beagle. Conclusions This study demonstrates a large genotype screening effort to identify the frequency and distribution of the MC1R R301C variant, one of the earliest mutations captured by canine domestication, and citizen science empowered characterization of its impact on coat color.

Comprehensive genetic testing combined with citizen science reveals a recently characterized ancient MC1R mutation associated with partial recessive red phenotypes in dog

Background: The Melanocortin 1 Receptor (MC1R) plays a central role in regulation of coat color determination in various species and is commonly referred to as the “E (extension) Locus”. Allelic variation of the MC1R gene is associated with coat color phenotypes EM (melanistic mask), EG (grizzle/domino) and e1-3 (recessive red) in dogs. In addition, a previous study of archeological dog specimens over 10,000 years of age identified a variant p.R301C in the MC1R gene that may have influenced coat color of early dogs.Results: Commercial genotyping of 11,750 dog samples showed the R301C variant of the MC1R gene was present in 35 breeds or breed varieties, at an allele frequency of 1.5% in the tested population. We detected no linkage disequilibrium between R301C and other tested alleles of the E locus. Based on current convention we propose that R301C should be considered a novel allele of the E locus, which we have termed eA for “e ancient red”. Phenotype analysis of owner-provided dog pictures reveals that the eA allele has an impact on coat color and is recessive to wild type E and dominant to the e alleles. In dominant black (KB/*) dogs it can prevent the phenotypic expression of the K locus, and the expressed coat color is solely determined by the A locus. In the absence of dominant black, eA/eA and eA/e genotypes result in the coat color patterns referred to in their respective breed communities as domino in Alaskan Malamute and other Spitz breeds, grizzle in Chihuahua, and pied in Beagle.Conclusions: This study demonstrates a large genotype screening effort to identify the frequency and distribution of the MC1R R301C variant, one of the earliest mutations captured by canine domestication, and citizen science empowered characterization of its impact on coat color.

Comprehensive genetic testing combined with citizen science reveals a recently characterized ancient MC1R mutation is associated with partial recessive red phenotypes in dog

Background: The Melanocortin 1 Receptor (MC1R) plays a central role in regulation of coat color determination in dogs and is commonly referred to as the “E (extension) Locus”. Allelic variation of the MC1R gene is associated with coat color phenotypes EM (melanistic mask), EG (grizzle/domino) and e1-3 (recessive red) in dogs. In addition, a previous study of archeological dog specimens over 10,000 years of age identified a variant p.R301C in the MC1R gene that may have influenced coat color of early dogs.Results: Commercial genotyping of 11,750 dog samples showed the R301C variant of the MC1R gene was present in 35 breeds or breed varieties, at an allele frequency of 1.5% in the tested population. We detected no linkage disequilibrium between R301C and other tested alleles of the E locus. Based on current convention we propose that R301C should be considered a novel allele of the E locus, which we have termed eA for “e ancient red”. Phenotype analysis of owner-provided dog pictures reveals that the eA allele has an impact on coat color and is recessive to wild type E and dominant to the e alleles. In dominant black (KB/*) dogs it can prevent the expression of the K locus, and the expressed coat color is solely determined by the A locus. In the absence of dominant black, eA/eA and eA/e genotypes result in the coat color patterns referred to in their respective breed communities as domino in Alaskan Malamute and other Spitz breeds, grizzle in Chihuahua, and pied in Beagle.Conclusions: This study demonstrates a large genotype screening effort to identify the frequency and distribution of the MC1R R301C variant, one of the earliest mutations captured by canine domestication, and citizen science empowered characterization of its impact on coat color.

Comprehensive genetic testing combined with citizen science reveals a recently characterized ancient MC1R mutation is associated with partial recessive red phenotypes in dog

Background The Melanocortin 1 Receptor (MC1R) plays a central role in regulation of coat color determination in dogs and is commonly referred to as the “E (extension) Locus”. Allelic variation of the MC1R gene is associated with coat color phenotypes EM (melanistic mask), EG (grizzle/domino) and e1–3 (recessive red) in dogs. In addition, a previous study of archeological dog specimens over 10,000 years of age identified a variant p.R301C in the MC1R gene that may have influenced coat color of early dogs. Results Commercial genotyping of 11,726 dog samples showed the R301C variant of the MC1R gene was present in 34 breeds or breed varieties, at an allele frequency of 1.48% in the tested population. We detected no linkage disequilibrium between R301C and other tested alleles of the E locus. Based on current convention we propose that R301C should be considered a novel allele of the E locus, which we have termed eA for “e ancient”. Phenotype analysis of owner-provided dog pictures reveals eA allele has an impact on coat color and is recessive to wild type E and dominant to the e alleles. In dominant black (KB/*) dogs it can prevent the expression of the K locus, and the expressed coat color is solely determined by the A locus. In the absence of dominant black, eA/eA and eA/e genotypes result in the coat color patterns referred to in their respective breed communities as domino in Alaskan Malamute and other Spitz breeds, grizzle in Chihuahua, and pied in Beagle. Conclusions This study demonstrates a large genotype screening effort to identify the frequency and distribution of the MC1R R301C variant, one of the earliest mutations captured by canine domestication, and citizen science empowered characterization of its impact on coat color.

Effect of Processed Cassava Peel Meal on Blood Chemistry Characteristics of Pullets

A 37-week feeding trial was conducted using 108 Dominant black strain of pullets to evaluate the effect of feeding diets containing retted cassava peel meal (RCPM) on their blood chemistry characteristics. The research was carried using a completely randomized design, from June 2009 to May 2010 at a private farm in Makurdi, Benue State, Nigeria. The RCPM used in this study was prepared and included at rates of 0%, 10% and 20% to replace maize of the control diet. The birds were randomly allotted to the three dietary groups. On 12th week, the birds in group T2 and T3 had a significant decline (P =.05) in total protein values when compared to the birds on the control diet. In the 24thweek, the cholesterol values increased significantly (P =.05) with increasing RCPM inclusions, also at the 24th week, the serum Alanine aminotransferase (ALT) values at 20% (T3) RCPM inclusion was significantly (P =.05) higher than values recorded in diets T1 and T2; but at the 37th week, values at the 10% (T2) inclusion rate was significantly lower (P =.05) than values recorded at the 0% (T1) and 20% (T3)RCPM inclusions respectively. The serum albumin values in the 37th week significantly increased (P =.05) in the treatment diets (T1 and T2) compared to the control diet (T1). The RCPM inclusions led to a significant decline (P =.05) in Serum aspartate aminotransferase (AST) values in the 24th week. It can be concluded that up to 20% RCPM can be used in pullet diets to replace maize without adverse effect on the blood chemistry characteristics of the birds.

Introduction

This book tells the history of college football at Historically Black Colleges and Universities (HBCUs) through the lens of Alonzo “Jake” Gaither’s playing and coaching career. After World War II, Gaither, as a coach, transformed Florida A&M University (FAMU) into the most dominant Black college football program over the next three decades. FAMU’s winning program was buttressed by the development of sporting congregations, a network of athletes, administrators, coaches, sportswriters, and fans that emerged in the first half of the 20th century. Finally, the growth of Black college football reflected a broader tension in African American higher education between integration and self-determination.

Inheritance of different coat colours in Newfoundland dogs in Poland

The aim of the study was to present the manner in which coat colour genes are inherited in the Newfoundland dog breed and to estimate the number of dogs with various coat colours in the Polish Newfoundland dog population in 2017. This population numbered 656 dogs, including 248 males and 408 females. The estimated number of dogs of this breed also included all registered puppies, broken down by gender and coat colour. The genes determining coat colour are described, including more precisely the genes responsible for the coat colour of the Newfoundland breed. According to FCI regulations, the coat colours for Newfoundland dogs are black, brown and black-and-white. Other colours, such as brown-and-white or blue, are not recognized for breeding purposes in Europe. The study found that the dominant black coat was predominant in the Polish Newfoundland dog population in 2017. These dogs could be heterozygous at some other loci and have undesirable alleles. The second most common coat colour was chocolate, while the fewest dogs had spotted coats. The group with spotted coats contained more males than females, in contrast to the other two colour variants. There were also individuals with the blue coat colour, which is not accepted for breeding, as the result of mating of parents with proper coat colours. An understanding of how dog coat colours are inherited and the need for tests to determine coat colour genotypes would make it possible to foresee the occurrence of incorrect colours in subsequent generations, which is crucial for Newfoundland dog breeders, whose goal is to obtain dogs whose coat colour is in line with the FCI standard.