Question

In Shepherd’s Purse, the fruit shape is controlled by
(a)Supplementary genes
(b)Complementary genes
(c)Duplicate genes
(d)Polymeric genes

Answer 1

It is a major mechanism through which new genetic material is generated during molecular evolution. It can emerge as a result of a few kinds of mistakes in DNA replication and repair machinery just as through accidental catch by selfish genetic components.

Complete answer:
A.Supplementary genes – Two independent pairs of genes, which interact to supply a replacement trait together, but each gene alone produces its own trait, are called Supplementary genes. eg: comb types in chickens
B.Complementary genes – Two independent pairs of genes, which interact to supply a trait together, but each gene alone doesn't show its effect, are called complementary genes. eg: flower color in Lathyrus
C.Duplicate genes – If the prevailing alleles of two genes loci produce a similar phenotype. Eg: a capsule of Shepherd's purse.
D.Polymeric gene-Two free predominant genes, regardless of whether present in homozygous or heterozygous condition, have a comparable phenotypic impact when present separately however produce an aggregate or twofold impact when discovered together. Eg: flower color of Lathyrus

Additional Information: Duplications emerge from an event named inconsistent traverse that occurs during meiosis between skewed homologous chromosomes. The chance of it happening is a function of the degree of sharing of repetitive elements between two chromosomes. The results of this recombination are duplication in the area of the exchange and a proportional deletion. Ectopic recombination is typically interceded by sequence likeness at the copy breakpoints, which structure direct repeats. Repetitive hereditary components like transposable components offer one wellspring of tedious DNA which will encourage recombination, and that they are frequently found at duplication breakpoints in plants and mammals.
So the correct answer is ‘Duplicate genes’.

Note: Gene duplications are an essential source of genetic novelty that can lead to evolutionary innovation. Duplication makes hereditary repetition, where the second duplicate of the gene is typically liberated from particular pressure—that is, transformations of it haven't any harmful impacts on its host living being. In the event that one duplicate of gene encounters a transformation that influences its unique capacity, the subsequent duplicate can work as an 'extra part' and still capacity effectively.