Abstract
Pulses are a key component of crop production systems in Southern Australia due to their rotational benefits and potential profit margins. However, cultivation in temperate cropping systems such as that of Southern Australia is limited by low soil water availability and subsoil constraints. This limitation of soil water is compounded by the irregular rainfall, resulting in the absence of plant available water at depth. An increase in the productivity of key pulses and expansion into environments and soil types traditionally considered marginal for their growth will require improved use of the limited soil water and adaptation to sub soil constrains. Roots serve as the interface between soil constraints and the whole plant. Changes in root system architecture (RSA) can be utilised as an adaptive strategy in achieving yield potential under limited rainfall, heterogenous distribution of resources and other soil-based constraints. The existing literature has identified a “‘Steep, Deep and Cheap” root ideotype as a preferred RSA. However, this idiotype is not efficient in a temperate system where plant available water is limited at depth. In addition, this root ideotype and other root architectural studies have focused on cereal crops, which have different structures and growth patterns to pulses due to their monocotyledonous nature and determinant growth habit. The paucity of pulse-specific root architectural studies warrants further investigations into pulse RSA, which should be combined with an examination of the existing variability of known genetic traits so as to develop strategies to alleviate production constraints through either tolerance or avoidance mechanisms. This review proposes a new model of root system architecture of “Wide, Shallow and Fine” roots based on pulse roots in temperate cropping systems. The proposed ideotype has, in addition to other root traits, a root density concentrated in the upper soil layers to capture in-season rainfall before it is lost due to evaporation. The review highlights the potential to achieve this in key pulse crops including chickpea, lentil, faba bean, field pea and lupin. Where possible, comparisons to determinate crops such as cereals have also been made. The review identifies the key root traits that have shown a degree of adaptation via tolerance or avoidance to water stress and documents the current known variability that exists in and amongst pulse crops setting priorities for future research.
Highlights
Pulses are a key seed crop both in Australia and globally due to their production value, their ability to increase soil nitrogen through fixation, forming a disease break in crop rotations, and for leaving residual moisture deeper in the soil profile for use by subsequent, deep-rooted crops [1,2]
As a result of the literature reviewed, proposed in this article is an alternative root architecture to the previously proposed “Steep, Deep and Cheap” ideotype [7], namely a “Wide, Shallow and Fine” root that is more aligned to the soil and climate conditions of the dryland cropping systems of Southeastern Australia (Figure 1b)
This review summarises pulse root system architecture and contributes to the identification of knowledge gaps to enable a better understanding of how specific pulse root traits can assist in improving pulse productivity in the range of soil types, seasonal conditions and agronomic management systems that dominate Southeastern Australia
Summary
Pulses are a key seed crop both in Australia and globally due to their production value, their ability to increase soil nitrogen through fixation, forming a disease break in crop rotations, and for leaving residual moisture deeper in the soil profile for use by subsequent, deep-rooted crops [1,2]. As a result of the literature reviewed, proposed in this article is an alternative root architecture to the previously proposed “Steep, Deep and Cheap” ideotype [7], namely a “Wide, Shallow and Fine” root that is more aligned to the soil and climate conditions of the dryland cropping systems of Southeastern Australia (Figure 1b). Dryland cropping systems in the medium- and low-rainfall zones of Australia typically experience unpredictable rainfall, often in insufficient amounts to replenish soil water throughout the potential rooting zone of annual crops, whilst in higher-rainfall locations, high precipitation: evaporation rates often lead to waterlogging during winter. Given the propensity for many pulse cropping regions to experience moderate inseason droughts, a new root ideotype that combines a range of root architectural traits is proposed This ideotype has a root length density that is concentrated in the upper soil layers to capture in-season rainfall before it is lost due to evaporation. The degree of root branching is not included in this review as investigation of this trait in pluses could not be found; it can be understood through root length, surface area and weight distribution
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