Cicer perennials harbor great resistances in particular environments in comparison to the resistances of other
herbaceous species. Although some
Cicer perennials are difficult to harvest, there have been studies to improve the
germination of particular species. Various studies highlight the specific resistances and improvements in
fitness of particular
Cicer perennial species. For example, one way in which
Cicer canariense, a perennial species, was able to improve its fitness is by the help of scientific experimentation.
Cicer canariense, a perennial species, has a lowered field emergence due to a hard seed coats. However, various methods such as chemical
scarification with concentrated
sulphuric acid as well as hot water treatment can be used to improve
germination. In one particular study, physical dormancy was overcome most effectively by mechanical
scarification and sulphur immersion. More studies regarding crop development could introduce this species as a potential food source. Another perennial species,
Cicer anatolicum, resists
chickpea ascochyta blight superior to the cultivated chickpea. Access to this resistance is barred due to hybridization barriers. A detailed study on endogenous hormones showed that interspecific hybrid production could occur if hormone profiles between the cultivated
chickpea and the perennial are synchronized. Further experimentation on hormone profiles could open up hybridization barriers between the modern chickpea and
Cicer anatolicum. Another barricade that could be overcome is the inability to cultivate specific
Cicer perennials in different parts of the world. Many
Cicer perennials and annual plants grow in different environments. So far, none of the perennial
Cicer species have been grown successfully in a tropical or subtropical setting in which annual
Cicer species grow. If the pollen of perennial species can be preserved for use in the different parts of the world in which annual species grow, then crossability techniques can be performed more effectively. This difficulty in use of the perennial
germplasm can be resolved by transshipping viable pollen across the ocean. If this issue were to be resolved, more
Cicer perennials could be planted in various portions of the world. Another constraint that affects the
Cicer species is the bollworm
Helicoverpa armigera, which is one of the biggest problems for their survival. Host plant resistance is an effective method to resolve these pests. A study found that perennials such as
C. canariense and
C. microphyllum have high resistance to
H. armigera compared to
C. judaicum, an annual plant. More experimentation on cross-breeding could give clues on the genetic origin of the proteins responsible for this resistance. Drought resistance is another opposition to overcome for many
Cicer perennials. About 90% of chickpea (
Cicer arietinum) in the world is grown with very little rainfall and where drought is a significant constraint to growth. A study assessed the resistance of drought of many perennials compared to annuals. When tested, the perennial wild
Cicer species recovered after wilting and drying out and also tolerated high temperatures. Of all the perennials tested crossbreeding with
Cicer anatolicum should be tested because of its close genetic affinities to the annual species. These resistances and improvements in the
Cicer perennial genome can be a potential reservoir of knowledge for the exploration of the genes that contribute to the perennials' traits. Drought and pest resistance along with scientific improvements in crop development play a huge role in the evolution of many
Cicer perennials. Further studies of genetic exchange and crossbreeding between
Cicer perennials could potentially benefit the traits of contemporary food-bearing crops and provide extensive knowledge for innovation. ==Evolution==