Nothing it is totally random. All the alleles on a chromosome will travel together, but then may change between chromosomes when crossover occurs.
The frequency of an allele in a gene pool is determined by counting the number of copies of that allele in a population. This frequency can change through evolutionary processes such as genetic drift, natural selection, mutation, and gene flow. Tracking allele frequencies helps scientists study population genetics and evolutionary dynamics.
anything goes
During Meiosis 1, each chromosome will line up alongside its homologous partner. For example in humans this means that there will be 23 homologous pairs lying side by side. The order in which they line up in is random, one pair will pass to each daughter cell, which pair goes into the daughter cell and with which one of any of the other pairs, depends on how the pairs are lined up in the parent cell. Since the pairs are lined up at random the combination of chromosomes that goes into the daughter cell at meiosis 1 is also random, this is called Independent segregation
law of segregation
The cell membrane, also known as the plasma membrane, is the organelle that helps the cell keep its shape and determines what goes in and out of the cell. It acts as a semi-permeable barrier, regulating the flow of molecules in and out of the cell.
There is only one allele for each trait that goes into a gamete. This happens after meiosis as well. This process allows for DNA to be the same over time as reproduction continues.
The FALSE statement is "A phenotype determines genotype." In reality, it is the genotype that determines the phenotype, as the genetic information (allele combinations) present in an individual's DNA influences their observable traits.
True or false? Yes, that's true. Why? So that the offspring will get one gene from the mother and the father. How? Through a process called meiosis. It is similar to mitosis, but there's an extra step where the chromatids divide, not just the chromosomes.
The male allele goes on the top row of the Punnett square, while the female allele goes on the side column. This arrangement allows for the combination of alleles to be determined for offspring based on the possible genetic combinations from each parent.
Depends on which one. One determines amount of air that goes into motor, other determines amount of air that goes out of motor.....
well its a multiple step process. first, the male gamete hasta whoo the female gamete. second, dinner is offered. if all goes well, there is an opportunity for third base. aka, the dirty. THey make sloppy druken love for roughly two minutes and then pass out on a street corner. the end.
The frequency of an allele in a gene pool is determined by counting the number of copies of that allele in a population. This frequency can change through evolutionary processes such as genetic drift, natural selection, mutation, and gene flow. Tracking allele frequencies helps scientists study population genetics and evolutionary dynamics.
The float determines how much gas goes through the carb.
well it depend on who got their first if the person across on the left got their first then it goes first and if then person across the right hand side got their first then it goes. just depend who got their first.
Males inherit one X and one Y chromosome, while females inherit two X chromosomes. During gamete formation, one member of each chromosome pair is randomly selected to be passed on to the offspring, ensuring genetic diversity. This process allows for genetic recombination and variation in offspring.
Down's Syndrome is caused due to the presence of an extra 21st chromosome, resulting in 3 sets of 21st chromosome instead of just 2. This is because during Anaphase II of Meiosis II non-disjunction occurs and instead of one 21st chromosome going into each gamete, both go into one of the gametes and none goes into the other. When a normal gamete fuses with the gamete with an extra21st chromosome, it forms a zygote with 3 sets of 21st chromosome instead of 2 and that is known as Down's Syndrome.
Alignment of the blade but most likely club face alignment.