In summary, an appropriate set of optimal interaction mechanisms need to be in place for healthy cell-wide functioning. In this context, a full understanding of cellular metabolism and mitochondrial diseases requires an understanding of mitochondrial communications with the rest of the cell, as well as within the organelle.
1.5. Mitochondrial motility
Mitochondrial motility, or trafficking, is critical for the survival of all cells. Neurons, which extend their axons and dendrites up to a meter, between two and three orders of magnitude greater than most other cells, are especially vulnerable to any inability by their mitochondria to get to sites with a high energy demand. At any instant of time, about 10–40% of the mitochondria are generally moving, with about half of those moving away from the cell body (anterograde, kinesin-dependent) and the rest towards the cell body (retrograde, dynein-dependent) (Schwarz 2013).
The distribution of mitochondria over long distances in the neurons is regulated by a complex molecular machinery that has evolved to match the very dynamic demand for energy with an optimal mitochondrial distribution (Schwarz 2013). Highly branched paths of the complex neuron geometry must be navigated, knowing where and when to stop. Machinery for fission and fusion can intersect with machinery for motility using feedforward and feedback mechanisms. Misregulation of motility can lead to neurodegeneration (Vanhauwaert et al. 2019).
The dendritic synapses are where the neurons receive signals from other neurons. Energy demand is greatest at the synapses and can change rapidly in response to almost instantaneous environmental changes. The same is true at the axonal synapses, which are used by neurons to transfer signaling downstream to subsequent neurons. Neuronal axons lie flat and are typically about a micron in diameter. Trafficking is along linear arrays of uniformly polarized microtubules, where the negative ends of the tubules are anchored in the cell body and the positive charge ends in the distal tips. Due to the local morphology, axonal mitochondria have separated from the reticulum and exist as discrete organelles of a dimension, typically 1–3 microns, with those in dendrites tending to be longer.
Mitochondria are a fundamental component for healthy living, supporting optimal functioning and efficient energy usage at all levels, thus avoiding numerous pathologies. In the discussion so far, we maintain that a significant controlling aspect of mitochondrial functioning is based on optimizations of a variety of defining characteristics. Here, motility and the placement of mitochondria within dendrites and axons can be viewed as optimal solutions, assuring sufficient energy at locations of high energy demand.
1.6. Cristae, ultrastructure and supercomplexes
Mitochondrial dynamics has evolved to define a broad array of actions and activities: already discussed are fission and fusion, and also cristae modifications, the constant changing of shape at the macro- and ultrastructural levels. Such modifications in shape are directly connected to their bioenergetic function. The cristae, where the respiratory chain complexes exist, have junctions of width between 20 nm and 40 nm. They control metabolite and protein access to the interior volume, known as the cristae lumen. They also control the apoptosis process of cell death. The junction structure and lumen are modified for more efficient respiration. So-called supercomplexes are created as part of the cristae remodeling, and these are required for optimal mitochondrial respiration. Slight morphological changes can fine-tune the efficiency of energy-producing respiration. There is a correlation between mitochondrial respiratory capacity and the number of cristae (Baker et al. 2019). A clear understanding of the supercomplexes, as well as the basis upon which cristae remodeling is optimized, can provide us with clues for clinical interventions that target respiratory-based diseases. We can hypothesize that morphological, mechanical and biochemical aspects play a role in cristae remodeling optimization, with the following discussion being of relevance.
The inner mitochondrial membrane and the cristae structure have only recently started to be understood. The inner membrane has the larger area even though it is enclosed within an outer membrane of a smaller area. To accommodate this, broad folds, called cristae, have evolved and project into the mitochondrial matrix where the bioenergetic processes occur. The observed morphology of the inner mitochondrial membrane is the result of the minimization of the system’s free energy. This free energy is a function of local bending energy and curvatures, the surface area, pressure differences and surface tension exerted by proteins. It appears, based on analytical models of these characterizing parameters, that the surface tension and tensile forces act as constraints on the morphology. The varied shapes of the cristae are defined by the stationary states of the above minimization. It appears that motor protein tensile forces are responsible for a stable inner membrane shape (Ghochani et al. 2010). The nanoscale cristae, regulated by molecular mechanisms, influence mitochondrial function (Mannella et al. 2013).
The tight coupling between cellular bioenergetics, metabolism, the inner membrane structure and mitochondrial function, as well as a continuous and high level of neuronal energy requirements, suggests links to understanding neurodegenerative diseases, bioenergetic dysfunction and mitochondrial diseases, and hopefully, to the identification and the enaction of clinical efforts for recovery. Such complex coupling suggests that constrained optimal decisions are a significant aspect of the governing of system behavior.
1.7. Mitochondrial diseases and neurodegenerative disorders
Mitochondrial dysfunction and disease are fundamental to the progression of the major neurodegenerative and neuropsychiatric diseases. Causes can include genetic defects, and intra- and extracellular environmental instigators, resulting in incurable neurodegeneration with motor, behavioral and cognitive losses of functioning, leading to death (Correia and Moreira 2018).
Primary mitochondrial defects affect all aspects of functioning. They are linked to diseases such as Alzheimer’s, Huntington’s, cancer, in the aging process (Lemonde and Rahman 2014) and are involved in the pathogenesis of multiple sclerosis (Adiele and Adiele 2019). Even relatively minor mitochondrial dysfunction can lead to Parkinson’s disease and Huntington’s disease, which also has psychiatric manifestations (Buhlman 2016).
Mitochondrial energy production occurs within the inner membrane, in the respiratory chain within the five enzymatic complexes that are housed in the matrix (see Figure 1.1). Nuclear DNA (nDNA) and the mitochondrial DNA (mtDNA) control the respiratory chain. Each cell has hundreds or thousands of mtDNA copies, and during cell division, any genetic mutations in mtDNA are distributed to the daughter cells randomly, resulting in both mutant- and wild (non-mutant)-type mtDNA copies. With further cell divisions, there is an accumulation of mutant cells. When the ratio of mutant to wild-type mtDNA copies grows beyond a certain threshold, which is random within a range, clinical symptoms of diseases can occur due to a misfiring of energy production. This group of diseases is known as mitochondrial disease. Different patients manifest their diseases at different stages, in different ways, due to the randomness of the relation between the above ratio and how the organism responds (Kurt and Topal 2013).
By way of fusion, damaged mtDNA is diluted, lowering the ratio between mutant and wild types below the threshold. Fission provides a mechanism to isolate components that become damaged due to age, or due to increased oxidative stress, for elimination. An imbalance between fission and fusion, discussed earlier as an optimal balancing, results in mitochondrial dysfunction (Panchal and Tiwari 2019).
Aging can lead to an accumulation of ROS, major contributors to oxidative stress,