This mock examination of Test: Plant Growth & Development – 1 for all of the major regions of development and growth. This includes 30 multiple choice questions covering each major region of development and growth. It covers regenerative growth, vegetative, reproductive and extra-plantar stages.
The question bank consists of 30 questions covering each region of growth and development. Each question is accompanied by an illustration that is used to explain its reasoning. This is an important part of the examination because it is used to show how different models can be compared. The Plant Growth & Development Explained booklet come with a CD-ROM that explains each model and how they can be compared. Each of the models in the bank can be used for one of the three different regions of the plant cycle as described below.
Single Cell Cycle – The first region of this exam deals with plants at their single-cell level. The question relates to the use of a virus to introduce a gene into an organism. The single-cell cycle is divided into three parts: the initiation of the proton motive force, the engulfment of an electron and the directional closure. After the initiation of the proton motive force, the engulfment of an electron takes place and that is followed by the next division of the cell.
Expression Vector Considered the Rest – This region of the examination deals with plant growth & development and the expression vector comprising the gene used to induce expression. For the sake of simplicity, this expression vector may be regarded as a ‘piece’ of a whole. The piece is put into an appropriate receptacle such as a petri dish and the process is carried out with the help of an appropriate medium. The process is repeated whenever a particular desired trait needs to be expressed. When this process is complete, then the petri dish is filled with culture media and the resultant culture is implanted into another plant.
Generation Of Plants – This region of the examination concerns plants that have already grown and which may be used as starters or seedlings for the production of various other species of organisms. For instance, it is quite possible to grow tomatoes (ovary) in order to produce black-eyed susans (claytons). However, before doing so, it is necessary to consider the sequence of events that led to the generation of the tomato plant. In the case of genetic plants, the sequence of events could be considered as being operable or able to be performed.
Nucleic Acid-Based Expression Vector Consisting Of Strand DNA An example of a non-operational region of the examination deals with the expression vector containing a sequence of genetic material that has been referred to as the nucleic acid. This particular sequence is called the nucleus, and is used to insert the genetic material into an appropriate region of the target plant tissue where it is needed for plant growth & development. This particular strand of DNA has proven to be one of the most efficient methods of plant development & growth, which is why it has been widely employed in the field of biotechnology.
Plant Growth & Development Using DNA This portion of the examination addresses the method of genetic engineering, which uses DNA as a means of creating controlled alterations in the genetic material that are necessary for the development of specific types of organisms. For instance, in this part of the examination, we will be examining whether a present invention provides plants comprising a nucleic acid that can be used for genetic engineering. As noted above, the procedure involved is usually referred to as nucleic acid expression, and is a relatively new development within the field of biotechnology.
Another embodiment of the present invention provides plants comprising of a constitutive promoter and operatively associated transcription activator. In this embodiment, the nucleic acid is expressed from an expression cassette in a way that is controlled by an external factor. The external factor is a temperature, and the cassette can be used as either a thermosensitive thermocycle a physical transcription activator or as a genetic promoter. The temperature that is used in this embodiment of the present invention is known as a biocompatible temperature.